US20050206585A1 - Display devices and integrated circuits - Google Patents
Display devices and integrated circuits Download PDFInfo
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- US20050206585A1 US20050206585A1 US11/131,004 US13100405A US2005206585A1 US 20050206585 A1 US20050206585 A1 US 20050206585A1 US 13100405 A US13100405 A US 13100405A US 2005206585 A1 US2005206585 A1 US 2005206585A1
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- G—PHYSICS
- G09—EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
- G09G—ARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
- G09G3/00—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
- G09G3/04—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions
- G09G3/06—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions using controlled light sources
- G09G3/12—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions using controlled light sources using electroluminescent elements
- G09G3/14—Semiconductor devices, e.g. diodes
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- G09G3/04—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions
- G09G3/16—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions by control of light from an independent source
- G09G3/18—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of a single character by selection from a plurality of characters, or by composing the character by combination of individual elements, e.g. segments using a combination of such display devices for composing words, rows or the like, in a frame with fixed character positions by control of light from an independent source using liquid crystals
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- G09G3/20—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
- G09G3/2085—Special arrangements for addressing the individual elements of the matrix, other than by driving respective rows and columns in combination
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- G09G3/20—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
- G09G3/34—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
- G09G3/36—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
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- H03K19/0175—Coupling arrangements; Interface arrangements
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- H03K19/02—Logic circuits, i.e. having at least two inputs acting on one output; Inverting circuits using specified components
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- G09G3/20—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
- G09G3/22—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters using controlled light sources
- G09G3/30—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters using controlled light sources using electroluminescent panels
- G09G3/32—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters using controlled light sources using electroluminescent panels semiconductive, e.g. using light-emitting diodes [LED]
- G09G3/3208—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters using controlled light sources using electroluminescent panels semiconductive, e.g. using light-emitting diodes [LED] organic, e.g. using organic light-emitting diodes [OLED]
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- G09G3/20—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
- G09G3/34—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
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- G09G3/34—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
- G09G3/36—Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
- G09G3/3611—Control of matrices with row and column drivers
- G09G3/3685—Details of drivers for data electrodes
- G09G3/3688—Details of drivers for data electrodes suitable for active matrices only
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- H01L2224/01—Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
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- H01L2224/24227—Connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked the item being non-metallic, e.g. insulating substrate with or without metallisation the HDI interconnect not connecting to the same level of the item at which the semiconductor or solid-state body is mounted, e.g. the semiconductor or solid-state body being mounted in a cavity or on a protrusion of the item
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- H01L27/02—Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components specially adapted for rectifying, oscillating, amplifying or switching and having at least one potential-jump barrier or surface barrier; including integrated passive circuit elements with at least one potential-jump barrier or surface barrier
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Definitions
- the present invention relates to devices and methods for handling information, and more particularly, in certain embodiments, to display devices and also to other types of apparatuses such as integrated circuits with position detectors and other apparatuses.
- pixel electrodes to control a display medium such as a liquid crystal layer in order to create an image.
- These pixel electrodes may control other types of display media such as electrophoretic display media or organic light emitting diodes (OLED).
- OLED organic light emitting diodes
- a pixel electrode works by creating locally an electric field relative to another electrode. A display medium is sandwiched between the two electrodes and reacts to this electric field.
- Well known examples of such types of displays are the active matrix liquid crystal displays used in modern laptop computers.
- FIG. 1 shows an example of a backplane for an active matrix display in the prior art.
- a plurality of pixel electrodes such as pixel electrode 9 C, are arranged in an array of rows and columns. Each row of pixel electrodes is controlled by a row electrode such as row electrodes 2 , 3 , and 4 .
- At least one transistor device is coupled to each pixel electrode in order to control the updating of new data to the pixel electrode in order to change the image being displayed.
- the field effect transistor (FET) 9 A couples the pixel electrode 9 C to the data line 1 on column 5 when row 2 receives a high voltage signal (e.g.
- each row receives a plurality of data in parallel substantially simultaneously as each row's signal line goes high, causing the gate electrode to allow the transistor device to conduct, thereby causing the data from the associated column to be written to the pixel electrode through the capacitor.
- the capacitor is merely optional and the capacitance of the FET device itself will be sufficient to store the charge for the pixel electrode to thereby maintain the pixel electrode at a certain voltage.
- each pixel cell includes a display driver such as display drivers 9 , 10 , and 11 which control associated pixel electrodes in the display shown in FIG. 1 .
- a display device includes a plurality of display drivers which includes a serial shift register, wherein the display drivers are located in the display area of the display device which is viewable.
- an integrated circuit which has a plurality of functionally symmetric interface pads, includes an instruction decoder which decodes instructions received through at least one of the pads.
- an integrated circuit includes a position detector which detects a position of the IC relative to a receptor substrate and provides a signal which is determined by the position.
- This IC may be used in an assembly which includes the receptor substrate.
- an integrated circuit includes a position detector which detects a position of the IC relative to a receptor substrate and also includes a configurable pad which is configurable depending upon the position as one of at least two of the following: an input pad, an output pad, or a no-operation pad.
- a layout of an integrated circuit has a plurality of functionally symmetric interface pads wherein two such pads are configurable.
- an assembly includes a receptor substrate and an IC attached to the substrate, and the IC includes a first logic circuit which provides a first function and a second logic circuit which provides a second function, and a selector which selects between the two functions such that the IC performs only the selected function.
- an assembly in yet another aspect of the present invention, includes a receptor substrate which includes an opening in the substantially planar region surrounding the opening and further includes a plurality of conductive layers attached over the substantially planar region.
- An integrated circuit is attached to the opening in the receptor substrate and includes electrical interface pads on a substantially planar surface which is substantially co-planar with the substantially planar region.
- the IC further includes a first logic circuit coupled to a first set of the electrical interface pads and which provides a first function and also includes a second logic circuit coupled to a second set of the electrical interface pads and which provides a second function which is different than the first function.
- An IC includes an instruction logic which is coupled to an electrical interface pad, where the instruction logic receives instruction commands to cause the integrated circuit to perform a particular function depending on the received instruction command.
- the IC further includes a clocked logic circuit which is coupled to the electrical interface pad. The clocked logic circuit receives a clock signal through the electrical interface pad which also provides the instruction commands to the IC.
- an exemplary embodiment of a circuit includes an input which receives a signal having first and second edges.
- the circuit further includes a pulse generation circuit which generates a pulse nested in time between consecutive first and second edges.
- the circuit also includes a power derivation circuit which is coupled to the input and which is coupled to the pulse generation circuit, where the power derivation circuit generates a voltage value which is used by logic within the circuit.
- an exemplary embodiment of a display device includes a two-dimensional array of pixels and an array of display drivers which are coupled to and which control the two-dimensional array of pixels.
- Each of the display drivers receives a clock signal and a data signal, wherein the clock signal and the data signal are bussed only substantially parallel to one axis of the display.
- an exemplary embodiment of a circuit for shifting a voltage level of a signal includes a first input to receive a clock signal having a pulse during each clock cycle, and a second input to receive a first voltage signal, and a current mirror circuit which is coupled to the first input and which is coupled to the second input.
- the current mirror controls the state of a node which is coupled to an output driver.
- the output driver shifts the first voltage signal to a second voltage signal when the node is in a first state.
- FIG. 1 shows an example of a prior art display.
- FIG. 2A illustrates an exemplary embodiment of a display according to one aspect of the present invention.
- FIG. 2B shows another exemplary embodiment of a display according to an aspect of the present invention.
- FIG. 2C shows a cross-sectional view of one exemplary embodiment of a display device according to the present invention.
- FIG. 3A shows an exemplary embodiment of a display according to one aspect of the present invention.
- FIG. 3B shows an exemplary embodiment of a display according to another aspect of the present invention.
- FIG. 3C shows an exemplary embodiment of a display according to yet another aspect of the present invention.
- FIG. 3D shows an exemplary embodiment of a display with functionally symmetric integrated circuits which may be deposited into openings in a receptor substrate through a fluidic self-assembly process according to one aspect of the present invention.
- FIG. 4A shows an exemplary embodiment of an IC which includes a position detector according to one aspect of the present invention.
- FIG. 4B shows another exemplary embodiment of an IC which includes a position detector according to one aspect of the present invention.
- FIG. 4C shows an enlarged view of a substantial portion of FIG. 4B .
- FIG. 5A shows the relationship in time between two clock waveforms.
- FIG. 5B shows one exemplary embodiment of a circuit according to one aspect of the present invention.
- FIG. 5C shows another exemplary embodiment of a circuit according to an aspect of the present invention.
- FIG. 5D shows a top view of an insulated gate field effect transistor in order to specify the width-length ratio measurements given throughout this description for field effect transistors.
- FIG. 6 shows an exemplary embodiment of a circuit used within the IC shown in FIG. 4B .
- FIG. 7A shows an exemplary embodiment of a circuit which is used within the IC shown in FIG. 4B .
- FIG. 7B shows an example of a receptor substrate with two blocks, each having an integrated circuit deposited (e.g. through fluidic self-assembly) into openings in the receptor substrate.
- FIG. 7C shows a cross-sectional view of a portion of the receiving substrate of FIG. 7B .
- FIG. 8 shows an exemplary embodiment of a circuit which is within the integrated circuit shown in FIG. 4B .
- FIG. 9A shows an exemplary circuit according to one aspect of the invention, which circuit may be used in the integrated circuit shown in FIG. 4B .
- FIG. 10 shows an exemplary embodiment of a circuit used within the IC shown in FIG. 4B .
- FIG. 11A shows an exemplary embodiment of a circuit which is used within the IC shown in FIG. 4B .
- FIG. 11B shows a timing waveform for use with circuits shown in FIG. 4B .
- FIG. 11C shows an exemplary embodiment of timing waveforms which may be used in conjunction with the circuits shown in FIG. 4B .
- FIG. 11D is a flowchart which depicts one embodiment of the operation of a command decoder used in the integrated circuit shown in FIG. 4B .
- FIG. 11E shows an exemplary flowchart of one method of operating a display according to the present invention.
- FIG. 12A shows an example of a circuit which may be used in the integrated circuit shown in FIG. 4B .
- FIG. 13A illustrates the interconnection of multiple display driver ICs, where each IC may be the same as that shown in FIG. 4B .
- FIG. 14A illustrates an alternative embodiment of an integrated circuit which may be used according to one aspect of the present invention.
- FIG. 14B illustrates an exemplary circuit which may be used within the integrated circuit shown in FIG. 14A .
- FIG. 14C is an example of a circuit which may be used in the integrated circuit shown in FIG. 14A .
- FIG. 14D shows the interconnection between multiple integrated circuits, such as multiple instances of the integrated circuit shown in FIG. 14A .
- FIG. 15A shows the layout of a display device according to one embodiment of the present invention and FIG. 15B shows an enlarged view of this layout.
- FIG. 2A shows a display system according to one aspect of the present invention.
- the display system includes a display data source 50 which provides four outputs 53 A, 54 A, 55 A, and 56 A which provide data to rows 53 , 54 , 55 , and 56 .
- Output 53 A will provide over time a stream of data (typically a serial stream) beginning with data for a last display driver along row 53 at the right end of the row and ending with data for the last display driver along the row 53 on the left side of the row 53 , which in this case is display driver 52 A.
- the data is shifted across over time from left to right in order to provide updated display data for the row 53 .
- Each display driver element such as display driver elements 52 A, 52 B, and 52 C, includes a memory element which is at least one stage of a shift register formed by each row, such as row 53 . Further details concerning various different circuits which may be used to provide this shift register formed by several display drivers along a row in the display 51 are provided below.
- the viewable display area for the display 51 is shown within the rectangular region which has been labeled 51 .
- the storage elements for the serial shift register along one row are actually within the viewable display area of the display 51 and are on the backplane of the display in this viewable area.
- each row receives a separate output from the display data source 50 . This allows for the display to be updated more rapidly than a display shown in FIG. 2B .
- a row such as row 53
- each portion is a serial shift register that receives an input from an output of the display data source, such as a modified version of the display data source 50 .
- parallel data may be shifted across a row (when more than one data row electrode is used) in certain embodiments.
- FIG. 2B illustrates another embodiment according to this aspect of the present invention.
- a display data source 60 has two outputs 69 and 70 , each of which provides data for three rows of display drivers. These rows are disposed within the viewable area of the display 61 .
- Display data for a new frame of an image to be displayed is shifted from the first display driver in the first row through the serial shift register formed by the three rows to the desired display driver.
- To update three rows, such as rows 63 , 64 , and 65 display data for the last display driver on row 65 is first loaded into the display driver 62 A and is then clocked or shifted to the next display driver 62 B and this is continued until this data reaches the desired display driver at the end (far right side) of row 65 .
- each display driver includes, according to one aspect of the present invention, a memory element within the display driver which is also within the viewable area of the display. The memory element is part of the serial shift register to allow the data to be shifted through the array as shown in FIG. 2B .
- FIG. 2C shows a cross-sectional view of a display according to one embodiment of the present invention.
- the display system includes a receiving substrate 81 which has receiving openings for integrated circuits 82 A and 82 B. These integrated circuits are display drivers in one embodiment, such as the display drivers 52 A and 52 B.
- FIG. 4B shows one detailed example of a display driver according to one embodiment of the invention.
- the receiving substrate may be a glass or a foil material or a flexible plastic material.
- An insulating layer 85 is attached to a top surface of the receptor substrate 81 and openings in the insulator are provided in order to make electrical contact through conductors, such as conductors 86 A, 87 A, 86 B, and 87 B.
- conductors 87 A and 86 B may be pixel electrodes and conductors 86 A and 87 B are electrodes used to provide signals, such as pixel data signals, to their respective integrated circuits 82 B and 82 A.
- a layer 88 may be provided on top of the pixel electrodes and the conductive signal electrodes in order to insulate these parts from the display media material 83 which may be a nematic liquid crystal, an electrophoretic display material, a polymer dispersed liquid crystal material, an organic light emitting diode material, a cholesteric liquid crystal material or other known display materials which can be driven by pixel electrodes or other types of display materials which may be controlled by electrodes.
- a counter electrode or cover glass electrode 84 is typically a thin layer of transparent indium tin oxide which is deposited upon a cover glass 90 which is transparent. Spacers 89 are attached to the layer 88 and to the cover glass 90 to provide a desired spacing between the counter electrode 84 and the layer 88 . It can be seen from FIG. 2C that all the necessary interconnections between the integrated circuits which are required to form a backplane for an active matrix display are formed in a single layer which does not require an insulating layer between layers of interconnect conductive material, such as conductive metal layers. Thus the display 80 as shown in FIG.
- 2C may be fabricated on a flexible substrate in a roll to roll web manufacturing process by applying only a single layer of a conductive material over the receiving substrate 81 and over the integrated circuits deposited into the receiving substrate without a need for a second or further conductive interconnect layers above this single layer of conductive material. This provides for greatly reduced manufacturing costs and improved yield and efficiency in the manufacturing process.
- FIG. 3A shows one exemplary embodiment of a display according to one aspect of the present invention.
- the display 100 includes display drivers 102 and 103 , each of which control more than one pixel electrode.
- each display driver in one embodiment acts as a serial storage element in a serial shift register along the row, shifting pixel data along row 101 from one display driver to the next display driver. This shifting may occur under the control of a clock signal which is provided in addition to a data signal.
- each display driver controls eight pixel electrodes by providing the necessary pixel data (usually as a voltage value) to each pixel electrode in order to locally control the display material to generate a viewable display.
- the integrated circuit shown in FIG. 4B is an example of a display driver, when that integrated circuit is used as a display driver, which may be used to control eight different pixel electrodes.
- FIG. 3B shows one example of a display 120 according to one aspect of the present invention.
- display data and clock data are bussed only substantially parallel to one axis of the display.
- this axis is the horizontal axis in which the display and clock signals are bussed substantially only parallel to the horizontal axis of the display 120 .
- each display driver such as display drivers 122 , 123 , 124 , and 125 control and provide pixel data to four pixel electrodes, such as pixel electrodes 121 A, 121 B, 121 C, and 121 D.
- Display drivers 122 and 123 are along one row and in one embodiment data may be shifted from display driver 122 to display driver 123 , where each display driver acts as a serial shift register memory element in a serial shift register formed along the row.
- data loaded onto the data row 126 is shifted across from left to right along this row which includes display drivers 122 and 123 .
- the shifting of the data through the row is controlled by a clock signal 127 .
- data row 128 provides data signals which are shifted from display driver 124 to display driver 125 under control of the clock signal 127 .
- a voltage power rail source is provided by voltage line 130 and a ground signal is provided by ground lines 131 A and 131 B.
- FIG. 3B These lines are interconnected to each of the display drivers as shown in FIG. 3B .
- An additional group of pixels, arranged as shown in FIG. 3B may exist above the array of FIG. 3B and another group of pixels, arranged as shown in FIG. 3B , may exist below the array of FIG. 3B . In this manner, a large display having thousands of pixels may be created with the arrangement shown in FIG. 3B .
- FIG. 3C shows another exemplary embodiment of aspects of the present invention.
- the display 150 includes a viewable display area 151 which includes within that area display pixels 160 - 167 , and display pixels 170 - 177 and which further includes display drivers 153 and 154 . Also included within the viewable display area are the data line 155 and the clock line 156 .
- the display of FIG. 3C includes display drivers which include memory elements which form a serial shift register. Multiple display drivers in the viewable area of the backplane, each having a storage segment of the shift register, forms a shift register in the display for clocking pixel data through the shift register, in this case from left to right as shown in FIG. 3C . In this case, shown in FIG.
- the pixel electrodes are formed in a numeral 8 format in order to display numbers within the viewable display area 151 . Display material within the region of each of these pixel electrodes will form a display picture element based upon the control of each individual pixel electrode.
- the display drivers such as display drivers 153 and 154 , are disposed within the viewable area of the display, and at least in one embodiment these display drivers include storage elements for the serial shift register. It will be appreciated that a cover may be placed over each display driver. This optional cover is shown as 154 A in the example of FIG. 3C . It will also be appreciated that the display drivers themselves need not be arranged in rows or columns.
- FIG. 3D shows an example of a display device which includes two integrated circuits 152 A and 153 A which together control eight pixel electrodes 189 A- 189 H.
- the pixel data is shifted from left to right, that is from the IC 152 A to the IC 153 A.
- the data line 155 A inputs data to the input 182 A and this data is shifted through output 183 A of IC 152 A to the input 182 B of the IC 153 A. If there are further display drivers to the right of IC 153 A which require pixel data, then the output pad 183 B of IC 153 A provides this data along the data signal line 155 A.
- the data is clocked through these ICs under control of the clock signal line 156 A which is coupled to the two ICs as shown in FIG. 3D .
- the metal or other conductive interconnect between the ICs and the pixel electrodes is such that there is no physical crossing of these metal lines in the interconnect layer.
- a display assembly may be fabricated without requiring a multilevel metal interconnect where each layer allows for a physical crossover because there is an insulating layer between a first metal layer and a second metal layer.
- the interconnection of an interconnect to an integrated circuit is shown by the absence of a circle within the pad shown in FIG. 3D .
- pad 180 A and 185 A do not have circles, indicating that pad 180 A receives the Vdh signal while pad 185 A receives the ground (Gnd) signal. It can be seen that the rotate A (ROTA) pad 184 A receives the clock signal which is also received by the clock pad 181 A.
- Four output pads 186 A, 187 A, 188 A, and 189 A drive four pixel electrodes from the integrated circuit 152 A as shown in FIG. 3D .
- the display device of FIG. 3D may be fabricated using conventional techniques wherein the integrated circuits 152 A and 153 A are disposed on a printed circuit board and separately drive pixel electrodes through the interconnections shown in FIG. 3D .
- the integrated circuits 152 A and 153 A may be fabricated in a single crystal semiconductor (e.g. silicon) wafer and then separated from the wafer and placed into a slurry. Then the slurry may be deposited over a receptor substrate which has openings in the substrate which have been designed to receive the separated integrated circuits in the slurry. An example of a resulting structure is shown in FIG. 2C .
- Fluidic self-assembly is known in the art; see, for example, U.S. Pat. No. 5,545,291. Methods for forming the separated integrated circuits are also described in co-pending U.S. patent application Ser. No. 09/433,605, which was filed on Nov. 2, 1999, which U.S. patent application is hereby incorporated herein by reference. It will be appreciated that the use of fluidic self-assembly will typically cause symmetrically shaped integrated circuits (e.g. a square) to be deposited into the openings in many orientations.
- symmetrically shaped integrated circuits e.g. a square
- the orientation of the IC cannot be controlled in the process.
- the electrical interface pads such as the pads shown by the squares within the ICs 152 A and 153 A must be functionally symmetric from an external interface point of view. That is, for example, the pad in the upper left corner of each IC after it is deposited into the opening should be an output pad such as the output pad 186 B. It can be seen from FIG.
- the rotational orientation of IC 152 A has four possible states such that, in one state, pad Out 1 A is in the upper left corner of the IC as it sits in an opening in a receptor substrate while in a second rotational state, pad Out 1 D is in the upper left corner, and in a third rotational state, pad Out 1 C is in the upper left corner, etc.
- the rotational orientation may be one of four orientations relative to a receptor substrate in the case of the display device shown in FIG. 3D . This will require that the integrated circuit be externally functionally symmetric even though internally its circuitry may be asymmetric. The following description will provide a detailed example of several embodiments which provide this functionality.
- the integrated circuit includes a position detector for determining its position which may be either a translational position relative to the receptor substrate or a rotational orientation of the integrated circuit relative to the opening in the receptor substrate.
- a position detector for determining its position which may be either a translational position relative to the receptor substrate or a rotational orientation of the integrated circuit relative to the opening in the receptor substrate.
- interface pads on the integrated circuit are configurable to provide different functions based upon the position of the integrated circuit. Further, in certain embodiments, the integrated circuit can provide different functions depending upon its position and these different functions may be provided selectively such that only one function is provided or concurrently in certain instances.
- the display may be a reflective monochrome or color active matrix display, or it may be a transmissive active matrix display such as those found on modern laptop computers (e.g. such as the Macintosh PowerBook G3 laptop from Apple Computer), or it may be an emissive display device (e.g. such as an OLED display).
- the display may require refreshing or may be bistable (which retains its display state without refreshing).
- FIG. 4A shows an example of an integrated circuit 190 according to one embodiment of the present invention.
- This circuit 190 may be used to create the integrated circuit 152 A or 153 A shown in FIG. 3D . It may be fabricated such that internally it is asymmetric but externally its electrical interface pads are arranged so that they are externally functionally symmetric such as the integrated circuit 152 shown in FIG. 3D . However, according to other aspects of the invention, an embodiment of the circuit 190 does not need to be functionally symmetric externally.
- the circuit 190 includes the microcontroller 191 which is optionally coupled to a position detector logic 208 .
- the microcontroller 191 is also coupled to a control bus 204 and may optionally be coupled to a data bus 205 .
- driver 200 is coupled to the data bus 205 and are also coupled to the control bus 204 .
- Each driver is coupled to its respective I/O (input/output) pad on the integrated circuit and they are also coupled to their respective pads for outputs as shown in FIG. 4A .
- driver 200 is coupled to pad I/O 4 labeled as pad 196 . It will be appreciated that this is an external electrical interface pad on the integrated circuit.
- the driver 200 is also coupled to the pads 192 which in this case are two output pads 4 A and 4 B. An example of such pads are shown in FIG. 3D , such as pads 186 A and 187 A.
- An example of pad 196 is pad 183 A shown in FIG. 3D .
- Pad 196 is in one embodiment a configurable pad which is configurable to be either an input pad or an output pad or a no-operation pad depending upon control signals provided to driver 200 .
- these control signals may come from the control bus 204 .
- the control signals may come from the control signal logic 209 which is coupled to each of the drivers 200 , 201 , 202 , and 203 .
- Control signal logic 209 receives signals from the position detector logic 208 which indicates the position of the integrated circuit 190 on a receiving substrate. This position is determined by an electrical signal received by the IC pad or pads 207 .
- the rotate A pad 184 A is an example of such a pad 207 (see FIG. 3D for the rotate A pad 184 A).
- Integrated circuit 190 may be fabricated into a single block of a semiconductor substrate and then separated from the substrate and floated into an opening on a receptor substrate to create the structure shown in FIG. 2C (e.g. floated by a fluidic self-assembly process) or it may be part of a larger conventional integrated circuit which is wire-bonded to a carrier or chip package and attached to a printed circuit board.
- the integrated circuit 190 is contained within a block of a semiconductor which is separated from a semiconductor substrate and then deposited into receptor sites in a receptor substrate through a fluidic self-assembly process (e.g. to achieve a structure similar to the structure shown in FIG. 7C ).
- the integrated circuit 190 will be deposited onto a receptor site, such as an opening in a receptor substrate (e.g. see FIG. 2C ).
- the exact position and orientation of the integrated circuit 190 cannot be controlled in this process. Accordingly, it is required to determine the position of the integrated circuit 190 relative to the receptor substrate. This requirement may be necessary to determine a translational position on the substrate (e.g. is the integrated circuit within a two-dimensional region or outside of a two-dimensional region on the receptor substrate) or the rotational orientation of the integrated circuit on a receptor site on the substrate (e.g. is the pad Out 1 A shown in FIG.
- the translational position of the integrated circuit is not detected but the rotational orientation is detected. In alternative embodiments, however, both may be detected or merely the translational location may be detected as described below.
- the position detector 208 receives signals from the pad or pads 207 and these signals are decoded to provide a position signal which may then be provided to the drivers 200 , 201 , 202 , and 203 through the control signal logic 209 .
- the position detector logic may provide a signal directly to the microcontroller 191 which can then provide signals to a control bus 204 to specify the desired functionality based on the position to each of the drivers 200 , 201 , 202 , and 203 .
- the control signal logic 209 provides the signals specifying the position directly to the drivers 200 , 201 , 202 , and 203 .
- These drivers after the position has been determined by the position detector logic 208 , then provide appropriate control signals so that the configurable pads, such as pads 196 , 197 , 198 , and 199 can be appropriately configured for the detected position.
- driver 200 may configure pad 196 as an input pad and driver 202 may configure pad 198 as an output pad allowing data to be, for example, shifted into pad 196 through driver 200 and then to the data bus 205 and then to the driver 202 for outputting of the data through the pad 198 .
- this would provide for the functionality shown in FIG. 3A in which the pixel data is shifted from left to right from display driver to display driver.
- the control signals to drivers 201 and 203 would cause the pads 197 and 199 to be configured to be no-operation pads.
- the signals coming into pad 196 would be supplied by the driver 200 directly to pads 192 (for data intended for those pads) or to the data bus 205 which is used to distribute the data to the other drivers.
- a parallel data bus 205 is shown in FIG. 4A
- a serial data bus such as that shown in FIG. 4B
- the microcontroller 191 may optionally be coupled to the data bus to receive data and to store it internally within the microcontroller (e.g. within a register in the microcontroller) which then can be used to put the data back on the bus and control the control bus 204 to cause another driver to receive its data under control of the microcontroller 191 .
- a specific example of a microcontroller 191 is provided below (e.g. see command decoder 231 in FIG. 4B which is described below).
- An example of a control bus is also described below (see control bus 232 shown in FIG. 4B and described below).
- the integrated circuit 190 when fabricated in a block of a semiconductor substrate which is then separated from the substrate and deposited through a fluidic self-assembly process onto a receptor substrate, is a case of a rotationally symmetric microcontroller or microprocessor. That is, the integrated circuit 190 includes a microcontroller or microprocessor in an integrated circuit which is externally functionally symmetric.
- the microcontroller or microprocessor may include many of the conventional components of a microcontroller or a microprocessor such as instruction decoders, instruction registers, data registers, ALU (arithmetic logic units), etc.
- this integrated circuit may be determined by the position detector logic 208 such that in one embodiment the integrated circuit provides one functionality in one position and another functionality in another position. Further, in yet another embodiment, the configurable pads may be configured to provide different signals or functions depending upon the position of the integrated circuit relative to the receptor substrate.
- FIG. 4B shows an exemplary embodiment of an integrated circuit 230 which may be used in a display device such as the display device 80 shown in FIG. 2C .
- the integrated circuit 230 may be used as the ICs 82 B and 82 A as shown in FIG. 2C .
- the integrated circuit 230 includes a command decoder 231 and a control bus 232 . It also includes a serial data bus 233 which is used to shift data among the drivers 235 A, 235 B, 235 C and 235 D.
- the command decoder 231 is coupled to a voltage supply circuit 234 which generates an internal voltage rail supply voltage as described below based upon a signal, which in this case is a clock signal.
- the integrated signal 230 also includes shift buffers 236 A, 236 B, 236 C, and 236 D which are coupled to the serial data bus 233 as shown in FIG. 4B .
- Each shift buffer such as shift buffer 236 A, is coupled to an I/O controller such as I/O controller 237 A which in turn is coupled to an electrical interface pad such as interface pad 239 A.
- the integrated circuit 230 includes four I/O controllers 237 A, 237 B, 237 C, and 237 D. Each of these I/O controllers is coupled to its respective I/O pad, such as pads 239 A, 239 B, 239 C and 239 D. These I/O pads are configurable input/output pads.
- these pads are configured to provide the desired functionality based upon the position of the integrated circuit 230 relative to a receptor substrate. For example, one of these I/O pads may be turned into an input pad while another of these I/O pads may be turned into an output pad and the other two I/O pads may be turned into no-operation pads.
- the position detector which in this case includes four orient circuits 238 A, 238 B, 238 C, and 238 D.
- orient circuit 238 A is coupled to the input enable input of the I/O controller 237 A and to the output enable input of the I/O controller 237 B.
- An input to the orient circuit 238 A is coupled to the position detector pad 240 A which corresponds to the rotate A pad 184 A shown in FIG. 3D .
- the orient circuit 238 B has an output coupled to the input enable input of the I/O controller 237 B and also coupled to the output enable input of I/O controller 237 C as shown in FIG. 4B .
- An input to the orient circuit 238 B is coupled to the position detector pad 240 B which corresponds to the pad ROTB shown in FIG. 3D .
- the orient circuit 238 C has an output coupled to the input enable input of the I/O controller 237 C and to the output enable input of the I/O controller 237 D.
- An input to the orient circuit 238 C is coupled to the position detector pad 240 C which corresponds to ROTC pad shown on the integrated circuits of FIG. 3D .
- the orient circuit 238 D has an output coupled to the input enable input of the I/O controller 237 D and also to the output enable input of the I/O controller 237 A.
- An input of the orient circuit 238 D is coupled to the position detector pad 240 D which corresponds to the pad ROTD pad on the integrated circuit shown in FIG. 3D . While further extensive, detailed description of the structure and operation of the integrated circuit 230 will be provided below, a brief introductory description will be provided here.
- the integrated circuit 230 provides the capability of driving up to eight segments or pixel electrodes with four output driving circuits 235 A, 235 B, 235 C, and 235 D.
- the command decoder 231 contains the command shift register for clocking in a series of four possible commands and decoding these commands which are then provided through the control bus 232 to the drivers 235 A, 235 B, 235 C, and 235 D. These commands or instructions are latched into an execution register to provide continuous command update capability.
- the eight high voltage outputs are derived from four two-bit blocks to provide four-sided symmetry. These high voltage outputs are latched separately to provide independent display updating, and to provide the capability to reset and invert the final output.
- the digital power supply uses the clock input as its source which provides fewer input requirements, and greater improved efficiency over generation from the high voltage supply 252 (Vdh).
- the orient circuits determine the data input and output to the entire integrated circuit 230 depending on which direction the integrated circuit settles into a receiving substrate in the fluidic self-assembly process. If, for example, the integrated circuit 230 settles into the receiving substrate such that the rotate A pad 240 A receives a clock signal (see, for example, FIG. 3D ) then shift buffer 236 A will cause an effective disconnect in the data bus 233 between the data out port of the driver circuit 235 D and the data in port of the driver circuit 235 A.
- pad 239 A will become an input pad and pad 239 B will become an output pad and pixel data or other data will get shifted into input pad 239 A through the I/O controller 237 A and through the shift buffer 236 A and then through the circuits 235 A, 236 B, 235 B, 236 C, 235 C, 236 D and then to the I/O controller 237 D and finally to the output pad 239 D.
- This will allow the display driver, when the IC 230 is used as a display driver, to shift data from one display driver to another display driver, such as the embodiment shown in FIG. 3D .
- each driver circuit such as driver circuit 235 A, will receive after all data has been shifted through the appropriate display data which then can be used to update to the outputs which are coupled to the driver, such as outputs 241 A or 241 B, etc.
- the command decoder 231 receives the various commands used to control the integrated circuit through the clock signal 279 , which in one embodiment is also providing, as noted herein, a power voltage rail for the operation of other logic within the integrated circuit 230 .
- FIG. 4C is an enlarged version of FIG. 4B showing much of the circuit shown in FIG. 4B .
- Table A shows a description of each of the pads of IC 230 .
- One IB/OD configured as input, and one as IC/OA output by orientation pins.
- RotA Input Rotational orientation control RotB signals Assertion of one signal RotC will select data input and output RotD pins Out1A Output High voltage outputs Out2A Out1B Out2B Out1C Out2C Out1D Out2D
- FIGS. 5A, 5B , and 5 C This aspect relates to a circuit in which a power voltage rail signal is derived from another signal which in one embodiment is a clock signal. This power voltage rail signal is then used by other logic within the integrated circuit to derive power for the other logic.
- the signal 250 may be a clock signal which has a regular duty phase which in this case is a 50% duty cycle.
- the signal 251 has a pulse nested within consecutive rising and falling edges of the clock signal 250 shown in FIG. 5A . That is, the pulse signal 251 rises only after the clock signal has settled in a high state and falls while the clock signal 250 is still within a high state.
- This signal 251 may be generated by a nested pulse control logic 256 from the signal 250 .
- the nested pulse control logic 256 generates at an output 257 the signal 251 which is supplied to a sampling circuit 258 as shown in FIG. 5B .
- the sampling circuit 258 also receives the input signal 255 which may be the clock signal 250 .
- the sampling circuit 258 generates a power supply signal which is stored in a power storage 259 which is then used to provide a power voltage rail output 260 .
- FIG. 5C shows one exemplary embodiment of the circuit shown in FIG. 5B .
- the clock input 279 is supplied to a nested pulse control circuit 275 which provides an output labeled clock subpulse 280 which is the same as the signal 251 shown in FIG. 5A .
- This output 280 controls a sampling circuit 276 which includes the transistor M 2020 as shown in FIG. 5C .
- the signal 280 is supplied to the transistor M 2020 , which is a P channel transistor, through the inverters formed by transistors M 2010 and M 2011 .
- the N channel device of this inverter, transistor M 2011 is coupled to ground 278 .
- the power storage is formed by the storage capacitors 277 which in one embodiment are twelve large field effect transistors wired as capacitors as shown in FIG. 5C .
- the voltage sampled from the high clock signal during the pulse is stored in these storage capacitors in order to provide the voltage Vdd which is labeled as 282 .
- FIG. 5C also shows that the clock signal 279 is used to generate other signals including a clock R (ClkR) signal 401 (through a resistor).
- FIG. 5C includes various transistors which are either P channel FETs or N channel FETs. The width/length ratio for these transistors are shown in FIG. 5C .
- FIG. 5D shows the length 291 relative to the width 292 for an FET device having a gate, source and drain, where the gate of the FET 290 is shown by a dashed line as slightly overlapping the source and drain regions of the FET 290 . It will be appreciated that other ratios may be utilized depending upon the desired characteristics of the circuit.
- FIG. 6 shows the power on reset circuit 281 which receives the voltage rail input 282 (Vdd) and the clock signal 279 input and provides a power on reset output 283 through the circuitry shown in FIG. 6 .
- This circuit generates a short pulse (a high pulse) for a few microseconds if the clock signal comes up quickly and thereafter the power on reset signal 283 goes low and remains low. If the clock signal comes up slowly (rises slowly) the power on reset signal will go high for a few microseconds after Vdd has retained its normal operating value (e.g. 5 volts).
- the power on reset circuit of FIG. 6 consists of a simple latch which is sized and capacitor coupled to force a consistent start up orientation.
- this circuit Upon application of the first rising edge of the clock signal, this circuit will assert until its own internal timing triggers the latch to flip, and this will deassert (drive low) the output signal 283 .
- the internal timing of the output signal 283 varies with the Vdd voltage levels, but provides a consistent pulse for resetting internal circuit nodes which receive the output signal 283 .
- FIG. 7A shows an example of a position detector circuit which in this case is the orient circuit such as orient circuit 238 A or 238 B or 238 C or 238 D.
- the orient circuit shown in FIG. 7A receives the Vdd input 282 and ground 278 and also a rotate in (ROTIN) input signal 301 .
- the rotate in signal 301 is coupled to the corresponding rotate or position detect pad such as pad 240 A for the corresponding orient circuit as shown in FIG. 4B .
- the rotate out or ROTOUT signal 302 provides the output from the orient circuit which is coupled to two I/O controllers as shown in FIG. 4B for the corresponding orient circuit.
- the rotate out signal 302 is coupled to the input enable input of the I/O controller 237 A and to the output enable input of the I/O controller 237 B. And in this instance, the rotate in input 301 is coupled to the rotate A pad 240 A.
- the inverse of the power on reset signal is received as the input 283 A and is coupled to a P channel device as shown in FIG. 7A .
- a latch formed by inverters 303 A and 303 B stores a state which provides the output signal to the output 302 .
- all orient circuits provide a low or zero output, and then the one orient circuit which is coupled to the position detector pad which is coupled to receive the clock signal (see, for example, the rotate A pad 184 A shown in FIG. 3D ) provides a high signal at the output 302 while the other orient circuits continue to provide a low signal at the output 302 of their circuits.
- all four orient circuits shown in FIG. 4B cooperate together to provide a position detector which specifies the internal functionality of the integrated circuit 230 depending upon the position detected by the position detector circuits. It can be seen that the orient circuit is disabled during a power up operation but subsequently one is enabled by the rising clock edge.
- Table B below shows the combinations which are possible for the integrated circuit 230 depending upon the position detected by the position detector logic which consists of the four orient circuits 238 A through 238 D.
- TABLE B Data Orientation Rotation signal asserted Input data pin Output data pin RotA IA/OC IB/OD RotB IB/OD IC/OA RotC IC/OA ID/OB RotD ID/OB IA/OC
- FIG. 7A shows one example of using position information specified by a receiving substrate to indicate to an integrated circuit which function or functions the circuit is to provide.
- FIG. 7B shows an alternative embodiment in which the translational position on a receiving substrate 305 specifies the functionality to be provided by the integrated circuit.
- the receiving substrate 305 includes a signal line 309 which is designed to connect to bonding pads on the integrated circuit deposited into the receiving substrate, which bonding pads are at the extreme corner of the integrated circuit.
- Signal line 308 is designed to be connected to the corresponding bonding pad which is next to the bonding pad at the corner as shown in FIG. 7B .
- the integrated circuit 306 which can be deposited in any one of four rotational orientations into the receiving substrate 305 , has interface pads 311 one of which will be coupled to a signal line 308 on the receiving substrate 305 .
- This can be seen in the cross-sectional view of FIG. 7C in which the IC 306 has been deposited into the receiving substrate 305 (e.g. such as through a fluidic self-assembly process) and then a metallization or other conductive layer 308 is provided on top of the IC 306 and on top of the receptor substrate 305 in order to make an electrical interconnect with the pad 311 .
- each integrated circuit may provide one function determined by its position or multiple functions determined by its position. Further, the position may select between one of two or more functions such that only that one function is performed.
- the signal lines may also provide programming signals to the electrical interface pads on the integrated circuits and these programming signals may determine the functionality provided by the circuitry within the integrated circuit depending upon the states of the programming signals.
- the pads at one point in time could provide one function and by changing the signal on the line or lines 309 , a different set of functions may be provided.
- FIG. 8 shows an example of an I/O controller circuit such as circuits 237 A, or 237 B, or 237 C, or 237 D of FIG. 4B .
- This circuit enables bi-directional capability for the digital data path through the integrated circuit 230 . It includes input protection and output buffers capable of driving pads such as pads 239 A, or 239 B, or 239 C, or 239 D, depending on the particular I/O controller circuit. While it will be appreciated that the circuit shown in FIG. 8 represents any one of the I/O controllers 237 A through 237 D, the following description, for purposes of simplicity, will assume that the circuit of FIG. 8 is the I/O controller 237 A which is coupled to the I/O pad 239 A and to the shift buffer circuit 236 A as shown in FIG.
- the input 353 of the circuit of FIG. 8 is the same as the input enable input of the I/O controller circuit 237 A shown in FIG. 4B .
- the input 352 of FIG. 8 is the same as the output enable input of the I/O controller 237 A as shown in FIG. 4B .
- Internal node 348 of FIG. 8 is the inverse of the input signal 353 .
- Internal node 349 of FIG. 8 is the inverse of the input signal 352 .
- the circuit of FIG. 8 is coupled to Vdd 282 and is also coupled to ground 278 as shown in FIG. 8 .
- the output 354 of the circuit of FIG. 8 is the same as the output which is labeled “input” of the I/O controller 237 A shown in FIG. 4B .
- the output 354 from FIG. 8 when this circuit of FIG. 8 is the I/O controller 237 A, is coupled to the pad in input of the shift buffer 236 A.
- the input 351 of FIG. 8 is the same as the input which is labeled “output” of the I/O controller 237 A.
- the I/O controller 237 A then if the input enable signal is asserted by the rotate A pad such that the input 353 is high then the I/O controller provides a signal path from the pad 350 to the output 354 , meaning that the I/O pad 239 A is functioning as an input pad. On the other hand, if the output enable input 352 is asserted, then the I/O controller is providing a signal path from the input 351 to the pad 350 such that the I/O pad 239 A is functioning as an output pad.
- Each of the corresponding I/O controllers 237 B, 237 C, and 237 D operates in a similar manner depending upon the control signals which are applied to the corresponding inputs 352 and 353 .
- the pad 350 will be placed in a no-operation state when neither input 352 and 353 is asserted.
- the I/O controllers of FIG. 4B provide for configuring its corresponding I/O pad (e.g. one of 239 A, 239 B, 239 C, and 239 D) as an either input pad or an output pad or a no-operation pad.
- FIG. 9A will now be referred to in describing yet another aspect of the present invention which provides an efficient, low power pulsed level shifting circuit according to one exemplary embodiment of this aspect.
- This circuit receives a low voltage input and also receives a clocked pulse signal.
- the low input signal is applied to devices in a current mirror which is passing current through two current paths under control of the clocked pulse input.
- One of these current paths controls a node to change a state of a node which in turn drives a driver to a shifted voltage state relative to the input voltage state.
- This level shifting circuit is used within the drivers 235 A, 235 B, 235 C and 235 D in one embodiment of the present invention.
- This level shifting circuit allows for a low voltage value, such as 5 volts, to be shifted to a higher voltage value, such as 20 volts, in order to drive certain types of display media in one embodiment of the present invention.
- the circuit 359 includes an input to receive a clocked signal having a pulse during each clock cycle and a second input to receive a first voltage signal, such as a low voltage signal.
- a current mirror circuit is coupled to the first input and is also coupled to the second input, and the current mirror circuit controls a state of a node.
- An output driver is coupled to the node and the output driver shifts a voltage level from the first voltage signal to a second voltage signal when the node is in a first state.
- the current mirror includes a first current path and a second current path and a first control electrode, such as a gate electrode, which is coupled to the first current path.
- a second control electrode, such as a gate electrode is coupled to the second current path and is coupled to the first control electrode.
- a transistor device which is a first transistor device in the first current path is substantially matched in size parameters to a second transistor device which is in the second current path.
- the pulse causes a current to flow in the second current path to set the node at the first state, and after the pulse, the node retains the first state with substantially no current flowing in the second current path.
- the level shifting circuit 359 receives an input low voltage signal at its input 360 and also receives a clocked pulse signal 280 . Further, the circuit 359 receives Vdd 282 as shown in FIG. 9A and the ground signal 278 .
- a current mirror formed by N channel FETs M 8 and M 9 and M 10 are coupled together at node 363 which receives the output of a weak inverter formed by devices M 10 and M 15 .
- M 10 sets the current in M 1 which determines a current in M 2 and M 8 and M 9 .
- M 10 controls the current through node 363 .
- the input to this inverter receives the pulsed clock signal 280 , and this pulse controls the flow of current in the current mirror which charges a node 362 .
- the node 362 controls the P channel FET M 6 which controls the output of the state of the output 361 .
- the current mirror circuit formed by the transistors M 8 and M 9 allows a communication between the low voltage section of the circuit and the high voltage section of the circuit without a large current consumption. Further, the pulses control the charging of the node 362 such that current flowing in the current mirror is substantially off when the signal 280 is low.
- An example of signal 280 is shown in FIG. 5A as signal 251 .
- the level shifter is driven in a pulsed manner with a periodic refreshing of the node 362 which in turn generates the output signal at output 361 .
- the output 361 is driven to high which is a voltage derived from the Vdh input 252 .
- the transistor M 7 When the input 360 is low the transistor M 7 will be turned on, which will pull down the output 361 to substantially close to ground 278 .
- This circuit 359 allows the control of a rail to rail high voltage signal (where the rail to rail transition is between Vdh and ground) using a much lower control voltage. Low power is consumed by modulating the current in the current mirror circuit by use of a very low duty cycle signal, in this case, the clock subpulse signal 280 .
- the on and the off states of the low voltage input 360 are passed to the transistor M 6 in a momentary fashion, and these on and off states are held on the transistor gate of transistor M 6 for most of the operating cycle with no current through the current mirrors, which include the first current path and the second current path formed by the devices M 8 and M 9 .
- Transistors M 3 through MS limit the gate/source voltage on M 6 when switching M 6 on.
- an additional device M 16 may be coupled to M 3 and to M 1 to further reduce power consumption.
- M 16 may be a P channel device (a P channel FET) having its gate coupled to the gate of M 3 and having its source coupled to the source of M 1 and its drain coupled to the drain of M 1 and this device may be sized to be the same size as transistor M 2 .
- FIG. 10 shows an example of a driver circuit which may be used as the driver circuits 235 A through 235 D of FIG. 4B .
- Each driver circuit such as circuits 235 A through 235 D, includes a two bit shift register, two buffer latches 390 and 391 , exclusive OR gating for output inversion under control of a polarity signal, and two high voltage level shifters 359 .
- the shift register timing is somewhat different from traditional shift registers in that due to power supply requirements, the data set up and hold times constitute most of the clock period, which creates a very small time in which the data can change.
- An internal delay in the shift buffer circuit e.g.
- the buffer registers formed by latches 390 and 391 allow the outputs to be reset and updated simultaneously as well as holding the outputs constant during a data load into the latches 381 and 382 .
- the level shifter circuits 359 convert the digital outputs to high voltage analog outputs to drive display segments such as pixel electrodes.
- Each driver circuit receives signals from the control bus 232 , such as the polarity signal or the reset signal.
- the reset signal is used to reset the pixels to a desired predetermined state and the polarity signal is used in those cases where the display media requires an inversion of the polarity of the signal over time (e.g. certain types of nematic liquid crystals require the polarity to be inverted over time as is well known in the art).
- the update signal from the control bus 232 causes pass gates 385 and 386 to allow the data outputs from the latches 381 and 382 to be inputted to the latches 390 and 391 which in turn drive the outputs 241 X.
- the polarity signal controls the output through the pass gates 392 as shown in FIG.
- the reset signal controls resetting of the state of the display pixels by activating the N channel FETs 388 to cause the inputs to the buffers 390 and 391 to be pulled to low.
- the shift data and shift data bar control signals are also from the control bus 232 and are used to control shifting of data through the shift register serial bus 233 internally within the IC 230 . It will be appreciated that along at least a row of the display or a portion of the row of the display, multiple ICs such as ICs 230 will be receiving these shift data and shift data bar commands to cause the pixel data to be shifted through multiple ICs along the row as well as internally within the IC 230 .
- the input 371 corresponds to the data in input on each of the drivers 235 A through 235 D.
- the output 372 corresponds to the data out output of each of the drivers 235 A through 235 D.
- buffer registers 381 and 382 are stages or elements within the shift register and these stages are separated by the pass gates such as pass gates 375 , 376 , 377 , and 378 .
- Inverters 379 and 380 are also part of the shift register as shown in FIG. 10 .
- FIG. 12A shows an example of a shift buffer circuit which may be used for each of the shift buffer circuits 236 A, 236 B, 236 C, and 236 D shown in FIG. 4 B.
- the shift output 540 of FIG. 12A is the same as the shift out output of each shift buffer circuit 236 A through 236 D.
- the shift in input 541 of FIG. 12A is the same as the shift in input of each shift buffer circuit 236 A through 236 D shown in FIG. 4B .
- the input 353 A receives its signal from the input enable input of the I/O controller which is coupled to the corresponding shift buffer. For example, in the case of the shift buffer 236 A of FIG.
- the input 353 A is coupled to the input enable input of I/O controller 237 A which is the input 353 shown in FIG. 8 .
- the input 354 A of FIG. 12A is coupled to the output 354 of the I/O controller circuit shown in FIG. 8 .
- Internal node 353 B of FIG. 12A is derived from inverting the signal at the input 353 A.
- the shift buffer circuit of FIG. 12A allows shifting through the serial bus 233 except for one point determined by the position detector logic which, as described above, electrically disconnects the serial ring formed initially by the bus 233 .
- FIGS. 11A, 11B , 11 C, 11 D, and 11 E will now be referred to in describing the command decoder circuit 231 as well as the overall operation of the integrated circuit 230 when used as a display driver in a display such as the display shown in FIG. 3D .
- the integrated circuit 230 may be used in non-display systems or systems which are displays and input systems (e.g. touch screen input) such as the system 550 shown in FIG. 13A .
- the command decoder circuit 231 includes a seven bit command shift register (formed by latches 416 , 417 , 418 , 419 , 420 , 421 , and 422 ) and a four bit execution register formed by latches created by inverter pairs 430 , inverter pair 431 , inverter pair 432 , and inverter pair 433 .
- the command decoder circuit 231 also includes a clock pulse detection logic (timing discriminator 408 ) and register control logic such as the command decoder status register 407 and the command awake sequence generator.
- the timing discriminator 408 receives the clock R signal 401 , which signal 401 is also used to generate internal signals 403 and 403 A which are used within the command decoder circuit 231 .
- the clock subpulse signal 280 is used to generate two signals 404 A and 404 which are also used within the command decoder circuit 231 as shown in FIG. 11A .
- the NAND gate 415 receives the signal 404 and also receives the signal 409 which is the command clock enable signal from the command awake sequence generator.
- Normal duty cycle clock signals such as those shown as 491 in FIG. 11B , maintain the clock data node 402 at a low state.
- a short clock pulse, such as pulse 492 shown in FIG. 11B causes the clock data node 402 to generate a high signal which, as will be described below, causes the command decoder status register 407 to generate the signals 406 and 406 A to “awaken” the command decoder circuit 231 .
- the signal 406 is applied as an input to the command awake sequence generator as shown in FIG. 11A to generate the command clock enable signal 409 and the command shift clear signal 410 .
- the second NAND gate in the command awake sequence generator which generates the signal 410 also receives the power on reset bar signal 283 A.
- the clock data node 402 is coupled to the pass gate 405 and is also coupled to the input of the command shift register, the first latch of which is latch 416 .
- Conventional pass gates and inverters are used throughout the command shift register as shown in FIG. 11A to create a shift register.
- the last stage of the shift register is the stop bit latch formed by the pair of inverters 423 .
- This stop bit latch provides a signal 411 which is inputted to the command decoder status register logic 407 .
- the command clock enable signal 409 is provided to one input of the NAND 415 and the signal 404 is provided as the other input to NAND 415 .
- P channel FET 447 receives the signal 410 which is used to clear the command shift register at the beginning of an awakening of the command decoder circuit 231 .
- This signal 410 is also coupled to the gates of the P channel FETs 440 through 446 to clear each of the latches 416 though 422 such that their output states are low (zero).
- Pass gates 425 , 426 , 427 , and 428 are enabled when signals 406 and 406 A are set such that the outputs CMD 1 through CMD 4 are provided to the input of the latches in the command storage register. The outputs from these command storage registers are then provided to the control bus 232 as shown in FIG. 11A .
- the incoming clock has two states: (1) normal operation with a 50% duty cycle (see clock signal 491 shown in FIG. 11B ), and (2) a command sequence operation with a 7% duty cycle (e.g. see pulse 492 shown in FIG. 11B ).
- the timing discriminator 408 detects the beginning of a command sequence by looking for the initial short clock pulse, such as pulse 492 .
- the loading of a command into the command decoder circuit 231 is further shown in FIGS. 11B and 11D .
- the timing discriminator 408 determines that it has received a short clock pulse and the clock data node 402 goes high, indicating the header bit of the command/instruction has been received.
- command awake signal 406 goes high after the clock data signal 402 goes high and the command storage register (formed by inverter pairs 430 through 433 ) is disconnected from the command shift register (formed by inverter pairs 416 through 423 ).
- the output commands stored in the command storage register are not affected by the new incoming command data stream.
- old instruction data in the command shift register is cleared to low with the assertion of the command shift clear bar signal 410 .
- the command clock enable signal 409 is asserted (by going high) and this allows the clock signal referred to as command clock (and its inverse, command clock bar) to be provided to the command shift register in order to clock the commands serially through the command shift register.
- commands 1 through 7 are loaded in reverse order as shown by the sequence 493 (shown in FIG. 11B ) which represents the command loading sequence 490 .
- Every clock cycle generated through the NAND gate 415 shifts instruction bits through the command shift register from left to right as shown in FIG. 11A .
- a short clock pulse at the clock data node 402 which represents the input to the command shift register represents a 1 or high bit and a long clock pulse bit represents a low or 0 bit.
- command 6 shown in FIG. 11B is low while command 2 shown in FIG. 11B is high.
- the initial start pulse 492 is a header bit which reaches the last stage (inverter pair 423 ) causing the stop bit signal to be asserted which stops the shifting by deasserting the command clock enable signal 409 , and the command awake signal 406 goes low causing the command shift register to update the command storage register.
- phase 494 normal execution follows as shown by phase 494 in FIG. 11B .
- this normal phase involves data loading and the display of data as shown in FIG. 11C .
- Tables C and D below show the various commands according to one embodiment of the present invention and the functions provided by these commands. TABLE C Command Code Sequence Command # Programmed in sequence Command 1 Load 2 Update 3 Polarity 4 Reset 5 Unused 6 Unused 7 Unused Note: Command data is loaded serially from command #7 down to command #1.
- the four possible commands used in the output drivers are:
- FIG. 11E shows one exemplary method of operating a display which uses a plurality of integrated circuits 230 such as the arrangement shown in FIG. 3D .
- operation 520 begins with a power up reset which places the display drivers in a default state in which display data is shifted into the display drivers, each of which include the shift register storage elements within the driver circuits, such as driver circuits 235 A through 235 D.
- operation 521 data is shifted in and as it is shifted in, it is displayed.
- the pixels can be set in a cleared state so that the display is blank or a homogeneous appearance until all data has been shifted in.
- the display may be manipulated or controlled with commands to the decoders in the display drivers. For example, the display may be reset again to clear the display or the polarity may be changed in those instances where this is required or new data may be loaded for a new image to be displayed by setting update to low and loading the new data and then setting update to high to display the new data.
- FIG. 13A shows the interconnection of two integrated circuits 230 according to one exemplary embodiment of the present invention.
- the clock and data signals are bussed substantially along only one axis of the display. Further, there is no physical crossing over of the interconnections on the receiving substrate which holds the integrated circuits 230 .
- FIGS. 14A, 14B , 14 C, and 14 D indicate an alternative embodiment of an integrated circuit 560 which is similar to integrated circuit 230 except it is less complex as can be seen from these figures. Many of the same components/circuits in the integrated circuit 230 are also used in the integrated circuit 560 . However, the command decoder circuit 231 is replaced by control circuit 561 which includes a simplified control bus 575 . This integrated circuit receives a clock signal 568 , a Vdd signal 566 , and a ground signal 567 . This integrated circuit is capable of driving four outputs but does include configurable I/O pads such as the pads 239 A through 239 D. This integrated circuit 560 also includes position detecting logic shown as circuits 563 A through 563 D.
- the driver circuits 562 A through 562 D are simplified and are shown in FIG. 14B .
- the position detection circuits are also simplified and shown in FIG. 14C .
- the integrated circuit 560 can be coupled together with other similar integrated circuits in the manner shown in FIG. 14D to form a display driver or other types of devices.
- the display driver shifts data horizontally or vertically along substantially one axis of the display.
- FIG. 15A shows an example of one particular embodiment of a display device using the integrated circuit 230 .
- This display device may, in one embodiment, be a flexible display for use in a smart card type credit card.
- a single layer of conductive interconnect in this case a metal interconnect, is used to interconnect the pixel electrodes and the integrated circuits 230 without requiring another layer of interconnect and an intervening insulating layer, thus greatly simplifying a roll to roll/web process for manufacturing a flexible display.
- a receiving substrate is a flexible plastic material into which holes are formed for the openings for the integrated circuits 230 .
- the flexible receiving substrate is strung from one roll (e.g.
- an interconnect layer which may be a separate flexible material also manufactured in a roll to roll/web process, may be applied to the receiving substrate after the integrated circuits 230 have been deposited into the openings. This will form the interconnect of the display device, allowing it to function with multiple pixel electrodes and multiple integrated circuits 230 .
- FIG. 15B shows an enlarged view of FIG. 15A so that the conductive lines can be more easily seen.
- the embodiment of FIG. 15A is similar to the embodiments shown in FIGS. 2C and 3C .
Abstract
Description
- The present invention relates to devices and methods for handling information, and more particularly, in certain embodiments, to display devices and also to other types of apparatuses such as integrated circuits with position detectors and other apparatuses.
- While the present invention has many aspects and embodiments, this section will focus on those aspects which relate to display devices. While there are a large number of various different types of display devices, one very common display device utilizes pixel electrodes to control a display medium such as a liquid crystal layer in order to create an image. These pixel electrodes may control other types of display media such as electrophoretic display media or organic light emitting diodes (OLED). Typically, a pixel electrode works by creating locally an electric field relative to another electrode. A display medium is sandwiched between the two electrodes and reacts to this electric field. Well known examples of such types of displays are the active matrix liquid crystal displays used in modern laptop computers.
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FIG. 1 shows an example of a backplane for an active matrix display in the prior art. As is well known, a plurality of pixel electrodes, such aspixel electrode 9C, are arranged in an array of rows and columns. Each row of pixel electrodes is controlled by a row electrode such asrow electrodes FIG. 1 , the field effect transistor (FET) 9A couples thepixel electrode 9C to thedata line 1 oncolumn 5 whenrow 2 receives a high voltage signal (e.g. 5 volts), causing the data value provided oncolumn 5 to be stored onto thecapacitor 9B which in turn causes the storage of a voltage value on thepixel electrode 9C. As is known in the art, each row receives a plurality of data in parallel substantially simultaneously as each row's signal line goes high, causing the gate electrode to allow the transistor device to conduct, thereby causing the data from the associated column to be written to the pixel electrode through the capacitor. It will be appreciated in certain embodiments that the capacitor is merely optional and the capacitance of the FET device itself will be sufficient to store the charge for the pixel electrode to thereby maintain the pixel electrode at a certain voltage. Thus the display is updated one row at a time where each row receives in parallel a plurality of data from the parallel columns, such ascolumns column 8 as shown inFIG. 1 . It will be appreciated that each pixel cell includes a display driver such asdisplay drivers FIG. 1 . - While the foregoing display architecture works well generally for many types of applications, it is well known that manufacturing these displays is expensive due to poor yields when the size of the display is large. Further, these displays are by necessity rigid as they are formed on glass and include layers such as polysilicon which are not flexible. Further, the use of polysilicon to create the active backplane of the display means that the electrical characteristics of the display are inferior to single crystal silicon integrated circuits.
- Various different aspects and embodiments of different inventions are described here. These different aspects include types of integrated circuits, assemblies with integrated circuits, display devices and electrical circuits, as well as methods relating to these devices.
- According to one aspect of the present invention, a display device includes a plurality of display drivers which includes a serial shift register, wherein the display drivers are located in the display area of the display device which is viewable.
- According to another aspect of the invention, an integrated circuit, which has a plurality of functionally symmetric interface pads, includes an instruction decoder which decodes instructions received through at least one of the pads.
- According to another aspect of the present invention, an integrated circuit (IC) includes a position detector which detects a position of the IC relative to a receptor substrate and provides a signal which is determined by the position. This IC may be used in an assembly which includes the receptor substrate.
- According to yet another aspect of the present invention, an integrated circuit includes a position detector which detects a position of the IC relative to a receptor substrate and also includes a configurable pad which is configurable depending upon the position as one of at least two of the following: an input pad, an output pad, or a no-operation pad.
- According to another embodiment and aspect of the present invention, a layout of an integrated circuit has a plurality of functionally symmetric interface pads wherein two such pads are configurable.
- According to another aspect of the invention, an assembly includes a receptor substrate and an IC attached to the substrate, and the IC includes a first logic circuit which provides a first function and a second logic circuit which provides a second function, and a selector which selects between the two functions such that the IC performs only the selected function.
- In yet another aspect of the present invention, an assembly includes a receptor substrate which includes an opening in the substantially planar region surrounding the opening and further includes a plurality of conductive layers attached over the substantially planar region. An integrated circuit is attached to the opening in the receptor substrate and includes electrical interface pads on a substantially planar surface which is substantially co-planar with the substantially planar region. The IC further includes a first logic circuit coupled to a first set of the electrical interface pads and which provides a first function and also includes a second logic circuit coupled to a second set of the electrical interface pads and which provides a second function which is different than the first function.
- An IC according to another aspect of the present invention includes an instruction logic which is coupled to an electrical interface pad, where the instruction logic receives instruction commands to cause the integrated circuit to perform a particular function depending on the received instruction command. The IC further includes a clocked logic circuit which is coupled to the electrical interface pad. The clocked logic circuit receives a clock signal through the electrical interface pad which also provides the instruction commands to the IC.
- According to another aspect of the present invention, an exemplary embodiment of a circuit includes an input which receives a signal having first and second edges. The circuit further includes a pulse generation circuit which generates a pulse nested in time between consecutive first and second edges. The circuit also includes a power derivation circuit which is coupled to the input and which is coupled to the pulse generation circuit, where the power derivation circuit generates a voltage value which is used by logic within the circuit.
- According to another aspect of the present invention, an exemplary embodiment of a display device includes a two-dimensional array of pixels and an array of display drivers which are coupled to and which control the two-dimensional array of pixels. Each of the display drivers receives a clock signal and a data signal, wherein the clock signal and the data signal are bussed only substantially parallel to one axis of the display.
- In yet another aspect of the present invention, an exemplary embodiment of a circuit for shifting a voltage level of a signal includes a first input to receive a clock signal having a pulse during each clock cycle, and a second input to receive a first voltage signal, and a current mirror circuit which is coupled to the first input and which is coupled to the second input. The current mirror controls the state of a node which is coupled to an output driver. The output driver shifts the first voltage signal to a second voltage signal when the node is in a first state.
- Other aspects and methods are also described herein.
- The present invention is illustrated by way of example and not limitation in the figures of the accompanying drawings in which like references indicate similar elements.
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FIG. 1 shows an example of a prior art display. -
FIG. 2A illustrates an exemplary embodiment of a display according to one aspect of the present invention. -
FIG. 2B shows another exemplary embodiment of a display according to an aspect of the present invention. -
FIG. 2C shows a cross-sectional view of one exemplary embodiment of a display device according to the present invention. -
FIG. 3A shows an exemplary embodiment of a display according to one aspect of the present invention. -
FIG. 3B shows an exemplary embodiment of a display according to another aspect of the present invention. -
FIG. 3C shows an exemplary embodiment of a display according to yet another aspect of the present invention. -
FIG. 3D shows an exemplary embodiment of a display with functionally symmetric integrated circuits which may be deposited into openings in a receptor substrate through a fluidic self-assembly process according to one aspect of the present invention. -
FIG. 4A shows an exemplary embodiment of an IC which includes a position detector according to one aspect of the present invention. -
FIG. 4B shows another exemplary embodiment of an IC which includes a position detector according to one aspect of the present invention. -
FIG. 4C shows an enlarged view of a substantial portion ofFIG. 4B . -
FIG. 5A shows the relationship in time between two clock waveforms. -
FIG. 5B shows one exemplary embodiment of a circuit according to one aspect of the present invention. -
FIG. 5C shows another exemplary embodiment of a circuit according to an aspect of the present invention. -
FIG. 5D shows a top view of an insulated gate field effect transistor in order to specify the width-length ratio measurements given throughout this description for field effect transistors. -
FIG. 6 shows an exemplary embodiment of a circuit used within the IC shown inFIG. 4B . -
FIG. 7A shows an exemplary embodiment of a circuit which is used within the IC shown inFIG. 4B . -
FIG. 7B shows an example of a receptor substrate with two blocks, each having an integrated circuit deposited (e.g. through fluidic self-assembly) into openings in the receptor substrate. -
FIG. 7C shows a cross-sectional view of a portion of the receiving substrate ofFIG. 7B . -
FIG. 8 shows an exemplary embodiment of a circuit which is within the integrated circuit shown inFIG. 4B . -
FIG. 9A shows an exemplary circuit according to one aspect of the invention, which circuit may be used in the integrated circuit shown inFIG. 4B . -
FIG. 10 shows an exemplary embodiment of a circuit used within the IC shown inFIG. 4B . -
FIG. 11A shows an exemplary embodiment of a circuit which is used within the IC shown inFIG. 4B . -
FIG. 11B shows a timing waveform for use with circuits shown inFIG. 4B . -
FIG. 11C shows an exemplary embodiment of timing waveforms which may be used in conjunction with the circuits shown inFIG. 4B . -
FIG. 11D is a flowchart which depicts one embodiment of the operation of a command decoder used in the integrated circuit shown inFIG. 4B . -
FIG. 11E shows an exemplary flowchart of one method of operating a display according to the present invention. -
FIG. 12A shows an example of a circuit which may be used in the integrated circuit shown inFIG. 4B . -
FIG. 13A illustrates the interconnection of multiple display driver ICs, where each IC may be the same as that shown inFIG. 4B . -
FIG. 14A illustrates an alternative embodiment of an integrated circuit which may be used according to one aspect of the present invention. -
FIG. 14B illustrates an exemplary circuit which may be used within the integrated circuit shown inFIG. 14A . -
FIG. 14C is an example of a circuit which may be used in the integrated circuit shown inFIG. 14A . -
FIG. 14D shows the interconnection between multiple integrated circuits, such as multiple instances of the integrated circuit shown inFIG. 14A . -
FIG. 15A shows the layout of a display device according to one embodiment of the present invention andFIG. 15B shows an enlarged view of this layout. - The subject invention will be described with reference to numerous details set forth below and the accompanying drawings which will illustrate the invention. The following description and drawings are illustrative of the invention and are not to be construed as limiting the invention. Numerous specific details are described to provide a thorough understanding of the present invention. However, in certain instances, well-known or conventional details are not described in order to not unnecessarily obscure the present invention in detail. Further, various aspects of the present invention will be described with reference to the use of aspects and embodiments of the invention in display systems. It will be appreciated that the reference to display systems is merely for purposes of illustration and are not to be construed as limiting the invention.
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FIG. 2A shows a display system according to one aspect of the present invention. The display system includes adisplay data source 50 which provides fouroutputs rows Output 53A will provide over time a stream of data (typically a serial stream) beginning with data for a last display driver alongrow 53 at the right end of the row and ending with data for the last display driver along therow 53 on the left side of therow 53, which in this case isdisplay driver 52A. The data is shifted across over time from left to right in order to provide updated display data for therow 53. Each display driver element, such asdisplay driver elements row 53. Further details concerning various different circuits which may be used to provide this shift register formed by several display drivers along a row in thedisplay 51 are provided below. The viewable display area for thedisplay 51 is shown within the rectangular region which has been labeled 51. Thus, the storage elements for the serial shift register along one row are actually within the viewable display area of thedisplay 51 and are on the backplane of the display in this viewable area. As shown inFIG. 2A , each row receives a separate output from thedisplay data source 50. This allows for the display to be updated more rapidly than a display shown inFIG. 2B . It will be appreciated that a row, such asrow 53, may in fact be segmented into multiple portions where each portion is a serial shift register that receives an input from an output of the display data source, such as a modified version of thedisplay data source 50. It will also be appreciated that parallel data may be shifted across a row (when more than one data row electrode is used) in certain embodiments. -
FIG. 2B illustrates another embodiment according to this aspect of the present invention. In this embodiment, adisplay data source 60 has twooutputs display 61. Display data for a new frame of an image to be displayed is shifted from the first display driver in the first row through the serial shift register formed by the three rows to the desired display driver. To update three rows, such asrows row 65 is first loaded into thedisplay driver 62A and is then clocked or shifted to thenext display driver 62B and this is continued until this data reaches the desired display driver at the end (far right side) ofrow 65. Similarly, data designed to be displayed at other display drivers are shifted through the serial shift register formed by the threerows rows output 70. As with the embodiment shown inFIG. 2A , each display driver includes, according to one aspect of the present invention, a memory element within the display driver which is also within the viewable area of the display. The memory element is part of the serial shift register to allow the data to be shifted through the array as shown inFIG. 2B . -
FIG. 2C shows a cross-sectional view of a display according to one embodiment of the present invention. The display system includes a receivingsubstrate 81 which has receiving openings forintegrated circuits display drivers FIG. 4B shows one detailed example of a display driver according to one embodiment of the invention. The receiving substrate may be a glass or a foil material or a flexible plastic material. An insulatinglayer 85 is attached to a top surface of thereceptor substrate 81 and openings in the insulator are provided in order to make electrical contact through conductors, such asconductors conductors conductors integrated circuits layer 88 may be provided on top of the pixel electrodes and the conductive signal electrodes in order to insulate these parts from thedisplay media material 83 which may be a nematic liquid crystal, an electrophoretic display material, a polymer dispersed liquid crystal material, an organic light emitting diode material, a cholesteric liquid crystal material or other known display materials which can be driven by pixel electrodes or other types of display materials which may be controlled by electrodes. A counter electrode orcover glass electrode 84 is typically a thin layer of transparent indium tin oxide which is deposited upon acover glass 90 which is transparent.Spacers 89 are attached to thelayer 88 and to thecover glass 90 to provide a desired spacing between thecounter electrode 84 and thelayer 88. It can be seen fromFIG. 2C that all the necessary interconnections between the integrated circuits which are required to form a backplane for an active matrix display are formed in a single layer which does not require an insulating layer between layers of interconnect conductive material, such as conductive metal layers. Thus thedisplay 80 as shown inFIG. 2C may be fabricated on a flexible substrate in a roll to roll web manufacturing process by applying only a single layer of a conductive material over the receivingsubstrate 81 and over the integrated circuits deposited into the receiving substrate without a need for a second or further conductive interconnect layers above this single layer of conductive material. This provides for greatly reduced manufacturing costs and improved yield and efficiency in the manufacturing process. -
FIG. 3A shows one exemplary embodiment of a display according to one aspect of the present invention. In this embodiment, thedisplay 100 includesdisplay drivers row 101 from one display driver to the next display driver. This shifting may occur under the control of a clock signal which is provided in addition to a data signal. As shown in FIG. 3A, each display driver controls eight pixel electrodes by providing the necessary pixel data (usually as a voltage value) to each pixel electrode in order to locally control the display material to generate a viewable display. The integrated circuit shown inFIG. 4B is an example of a display driver, when that integrated circuit is used as a display driver, which may be used to control eight different pixel electrodes. -
FIG. 3B shows one example of adisplay 120 according to one aspect of the present invention. In thisdisplay 120, display data and clock data are bussed only substantially parallel to one axis of the display. As shown inFIG. 3B , this axis is the horizontal axis in which the display and clock signals are bussed substantially only parallel to the horizontal axis of thedisplay 120. In this example, each display driver, such asdisplay drivers pixel electrodes Display drivers display driver 122 to displaydriver 123, where each display driver acts as a serial shift register memory element in a serial shift register formed along the row. Thus data loaded onto the data row 126 is shifted across from left to right along this row which includesdisplay drivers clock signal 127. Similarly, on the bottom half of the display, data row 128 provides data signals which are shifted fromdisplay driver 124 to displaydriver 125 under control of theclock signal 127. A voltage power rail source is provided byvoltage line 130 and a ground signal is provided byground lines FIG. 3B . Note that there is no physical crossover of electrically conductive interconnects, and thus all electrically conductive interconnects required by thedisplay 120 may be formed in a single layer of electrically conductive interconnects, resulting in a structure which is similar toFIG. 2C . An additional group of pixels, arranged as shown inFIG. 3B , may exist above the array ofFIG. 3B and another group of pixels, arranged as shown inFIG. 3B , may exist below the array ofFIG. 3B . In this manner, a large display having thousands of pixels may be created with the arrangement shown inFIG. 3B . -
FIG. 3C shows another exemplary embodiment of aspects of the present invention. Thedisplay 150 includes aviewable display area 151 which includes within that area display pixels 160-167, and display pixels 170-177 and which further includesdisplay drivers data line 155 and theclock line 156. As with the example shown inFIG. 3A , the display ofFIG. 3C includes display drivers which include memory elements which form a serial shift register. Multiple display drivers in the viewable area of the backplane, each having a storage segment of the shift register, forms a shift register in the display for clocking pixel data through the shift register, in this case from left to right as shown inFIG. 3C . In this case, shown inFIG. 3C , the pixel electrodes are formed in anumeral 8 format in order to display numbers within theviewable display area 151. Display material within the region of each of these pixel electrodes will form a display picture element based upon the control of each individual pixel electrode. It is noted that the display drivers, such asdisplay drivers FIG. 3C . It will also be appreciated that the display drivers themselves need not be arranged in rows or columns. -
FIG. 3D shows an example of a display device which includes twointegrated circuits pixel electrodes 189A-189H. In the case of the display device ofFIG. 3D , the pixel data is shifted from left to right, that is from theIC 152A to theIC 153A. In particular, thedata line 155A inputs data to theinput 182A and this data is shifted throughoutput 183A ofIC 152A to theinput 182B of theIC 153A. If there are further display drivers to the right ofIC 153A which require pixel data, then theoutput pad 183B ofIC 153A provides this data along the data signalline 155A. The data is clocked through these ICs under control of theclock signal line 156A which is coupled to the two ICs as shown inFIG. 3D . It can be seen from the layout ofFIG. 3D that the metal or other conductive interconnect between the ICs and the pixel electrodes is such that there is no physical crossing of these metal lines in the interconnect layer. Thus referring back toFIG. 2C , a display assembly may be fabricated without requiring a multilevel metal interconnect where each layer allows for a physical crossover because there is an insulating layer between a first metal layer and a second metal layer. The interconnection of an interconnect to an integrated circuit is shown by the absence of a circle within the pad shown inFIG. 3D . Thus, for example,pad pad 180A receives the Vdh signal whilepad 185A receives the ground (Gnd) signal. It can be seen that the rotate A (ROTA)pad 184A receives the clock signal which is also received by theclock pad 181A. Fouroutput pads integrated circuit 152A as shown inFIG. 3D . - It will be appreciated that the display device of
FIG. 3D may be fabricated using conventional techniques wherein theintegrated circuits FIG. 3D . However, in one particular embodiment of the present invention, theintegrated circuits FIG. 2C . The slurry is deposited over the receiving substrate in a fluid and the integrated circuits self-assemble into the openings through a process referred to as fluidic self-assembly. Fluidic self-assembly is known in the art; see, for example, U.S. Pat. No. 5,545,291. Methods for forming the separated integrated circuits are also described in co-pending U.S. patent application Ser. No. 09/433,605, which was filed on Nov. 2, 1999, which U.S. patent application is hereby incorporated herein by reference. It will be appreciated that the use of fluidic self-assembly will typically cause symmetrically shaped integrated circuits (e.g. a square) to be deposited into the openings in many orientations. That is, the orientation of the IC cannot be controlled in the process. Thus, at least in many instances, the electrical interface pads such as the pads shown by the squares within theICs output pad 186B. It can be seen fromFIG. 3D that the rotational orientation ofIC 152A has four possible states such that, in one state, pad Out1A is in the upper left corner of the IC as it sits in an opening in a receptor substrate while in a second rotational state, pad Out1D is in the upper left corner, and in a third rotational state, pad Out1C is in the upper left corner, etc. Thus it can be seen that the rotational orientation may be one of four orientations relative to a receptor substrate in the case of the display device shown inFIG. 3D . This will require that the integrated circuit be externally functionally symmetric even though internally its circuitry may be asymmetric. The following description will provide a detailed example of several embodiments which provide this functionality. In one case, the integrated circuit includes a position detector for determining its position which may be either a translational position relative to the receptor substrate or a rotational orientation of the integrated circuit relative to the opening in the receptor substrate. Further, in certain embodiments, interface pads on the integrated circuit are configurable to provide different functions based upon the position of the integrated circuit. Further, in certain embodiments, the integrated circuit can provide different functions depending upon its position and these different functions may be provided selectively such that only one function is provided or concurrently in certain instances. - The following description, for purposes of illustration, focuses upon the use of these integrated circuits for display devices. It will be appreciated, however, that these integrated circuits may be used in other types of systems including antenna arrays or detector systems or sensor systems or to provide multiple functions concurrently such as a display and touch screen system where each integrated circuit functions as a display driver as well as providing the circuitry necessary for the functionality of a touch screen sensor. It will also be appreciated that when the integrated circuits of the present invention are used in display devices, for example, as display drivers, that various different types of displays may be created. For example, the display may be a reflective monochrome or color active matrix display, or it may be a transmissive active matrix display such as those found on modern laptop computers (e.g. such as the Macintosh PowerBook G3 laptop from Apple Computer), or it may be an emissive display device (e.g. such as an OLED display). The display may require refreshing or may be bistable (which retains its display state without refreshing).
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FIG. 4A shows an example of anintegrated circuit 190 according to one embodiment of the present invention. Thiscircuit 190 may be used to create theintegrated circuit FIG. 3D . It may be fabricated such that internally it is asymmetric but externally its electrical interface pads are arranged so that they are externally functionally symmetric such as theintegrated circuit 152 shown inFIG. 3D . However, according to other aspects of the invention, an embodiment of thecircuit 190 does not need to be functionally symmetric externally. Thecircuit 190 includes themicrocontroller 191 which is optionally coupled to aposition detector logic 208. Themicrocontroller 191 is also coupled to acontrol bus 204 and may optionally be coupled to adata bus 205. Fourdrivers data bus 205 and are also coupled to thecontrol bus 204. Each driver is coupled to its respective I/O (input/output) pad on the integrated circuit and they are also coupled to their respective pads for outputs as shown inFIG. 4A . For example,driver 200 is coupled to pad I/O4 labeled aspad 196. It will be appreciated that this is an external electrical interface pad on the integrated circuit. Thedriver 200 is also coupled to thepads 192 which in this case are twooutput pads FIG. 3D , such aspads pad 196 ispad 183A shown inFIG. 3D .Pad 196 is in one embodiment a configurable pad which is configurable to be either an input pad or an output pad or a no-operation pad depending upon control signals provided todriver 200. In one embodiment, these control signals may come from thecontrol bus 204. In another embodiment, the control signals may come from thecontrol signal logic 209 which is coupled to each of thedrivers Control signal logic 209 receives signals from theposition detector logic 208 which indicates the position of theintegrated circuit 190 on a receiving substrate. This position is determined by an electrical signal received by the IC pad orpads 207. The rotate Apad 184A is an example of such a pad 207 (seeFIG. 3D for the rotate Apad 184A). -
Integrated circuit 190 may be fabricated into a single block of a semiconductor substrate and then separated from the substrate and floated into an opening on a receptor substrate to create the structure shown inFIG. 2C (e.g. floated by a fluidic self-assembly process) or it may be part of a larger conventional integrated circuit which is wire-bonded to a carrier or chip package and attached to a printed circuit board. However, for the following embodiments which will be described, it will be assumed that theintegrated circuit 190 is contained within a block of a semiconductor which is separated from a semiconductor substrate and then deposited into receptor sites in a receptor substrate through a fluidic self-assembly process (e.g. to achieve a structure similar to the structure shown inFIG. 7C ). Theintegrated circuit 190 will be deposited onto a receptor site, such as an opening in a receptor substrate (e.g. seeFIG. 2C ). The exact position and orientation of theintegrated circuit 190 cannot be controlled in this process. Accordingly, it is required to determine the position of theintegrated circuit 190 relative to the receptor substrate. This requirement may be necessary to determine a translational position on the substrate (e.g. is the integrated circuit within a two-dimensional region or outside of a two-dimensional region on the receptor substrate) or the rotational orientation of the integrated circuit on a receptor site on the substrate (e.g. is the pad Out1A shown inFIG. 3D in the upper left corner or the upper right corner or the lower right corner or the lower left corner of the opening on the receptor substrate relative to the position of interconnect lines on the receptor substrate). In one embodiment of the present invention, the translational position of the integrated circuit is not detected but the rotational orientation is detected. In alternative embodiments, however, both may be detected or merely the translational location may be detected as described below. Theposition detector 208 receives signals from the pad orpads 207 and these signals are decoded to provide a position signal which may then be provided to thedrivers control signal logic 209. Alternatively, the position detector logic may provide a signal directly to themicrocontroller 191 which can then provide signals to acontrol bus 204 to specify the desired functionality based on the position to each of thedrivers FIG. 4B ) thecontrol signal logic 209 provides the signals specifying the position directly to thedrivers position detector logic 208, then provide appropriate control signals so that the configurable pads, such aspads driver 200 may configure pad 196 as an input pad anddriver 202 may configure pad 198 as an output pad allowing data to be, for example, shifted intopad 196 throughdriver 200 and then to thedata bus 205 and then to thedriver 202 for outputting of the data through thepad 198. In this case, this would provide for the functionality shown inFIG. 3A in which the pixel data is shifted from left to right from display driver to display driver. At the same time the control signals todrivers pads pad 196 would be supplied by thedriver 200 directly to pads 192 (for data intended for those pads) or to thedata bus 205 which is used to distribute the data to the other drivers. While aparallel data bus 205 is shown inFIG. 4A , it will be appreciated that a serial data bus, such as that shown inFIG. 4B , may also be utilized as an alternative embodiment. Themicrocontroller 191 may optionally be coupled to the data bus to receive data and to store it internally within the microcontroller (e.g. within a register in the microcontroller) which then can be used to put the data back on the bus and control thecontrol bus 204 to cause another driver to receive its data under control of themicrocontroller 191. A specific example of amicrocontroller 191 is provided below (e.g. seecommand decoder 231 inFIG. 4B which is described below). An example of a control bus is also described below (seecontrol bus 232 shown inFIG. 4B and described below). - It will be appreciated that the
integrated circuit 190, when fabricated in a block of a semiconductor substrate which is then separated from the substrate and deposited through a fluidic self-assembly process onto a receptor substrate, is a case of a rotationally symmetric microcontroller or microprocessor. That is, theintegrated circuit 190 includes a microcontroller or microprocessor in an integrated circuit which is externally functionally symmetric. The microcontroller or microprocessor may include many of the conventional components of a microcontroller or a microprocessor such as instruction decoders, instruction registers, data registers, ALU (arithmetic logic units), etc. Further, the functionality of this integrated circuit may be determined by theposition detector logic 208 such that in one embodiment the integrated circuit provides one functionality in one position and another functionality in another position. Further, in yet another embodiment, the configurable pads may be configured to provide different signals or functions depending upon the position of the integrated circuit relative to the receptor substrate. -
FIG. 4B shows an exemplary embodiment of anintegrated circuit 230 which may be used in a display device such as thedisplay device 80 shown inFIG. 2C . In particular, theintegrated circuit 230 may be used as theICs FIG. 2C . Theintegrated circuit 230 includes acommand decoder 231 and acontrol bus 232. It also includes aserial data bus 233 which is used to shift data among thedrivers command decoder 231 is coupled to avoltage supply circuit 234 which generates an internal voltage rail supply voltage as described below based upon a signal, which in this case is a clock signal. Theintegrated signal 230 also includesshift buffers serial data bus 233 as shown inFIG. 4B . Each shift buffer, such asshift buffer 236A, is coupled to an I/O controller such as I/O controller 237A which in turn is coupled to an electrical interface pad such asinterface pad 239A. Theintegrated circuit 230 includes four I/O controllers pads integrated circuit 230 relative to a receptor substrate. For example, one of these I/O pads may be turned into an input pad while another of these I/O pads may be turned into an output pad and the other two I/O pads may be turned into no-operation pads. - The functionality of the pads will be specified in one embodiment by the position detector which in this case includes four
orient circuits FIG. 4B , orientcircuit 238A is coupled to the input enable input of the I/O controller 237A and to the output enable input of the I/O controller 237B. An input to theorient circuit 238A is coupled to theposition detector pad 240A which corresponds to the rotate Apad 184A shown inFIG. 3D . Theorient circuit 238B has an output coupled to the input enable input of the I/O controller 237B and also coupled to the output enable input of I/O controller 237C as shown inFIG. 4B . An input to theorient circuit 238B is coupled to theposition detector pad 240B which corresponds to the pad ROTB shown inFIG. 3D . Theorient circuit 238C has an output coupled to the input enable input of the I/O controller 237C and to the output enable input of the I/O controller 237D. An input to theorient circuit 238C is coupled to theposition detector pad 240C which corresponds to ROTC pad shown on the integrated circuits ofFIG. 3D . Theorient circuit 238D has an output coupled to the input enable input of the I/O controller 237D and also to the output enable input of the I/O controller 237A. An input of theorient circuit 238D is coupled to theposition detector pad 240D which corresponds to the pad ROTD pad on the integrated circuit shown inFIG. 3D . While further extensive, detailed description of the structure and operation of theintegrated circuit 230 will be provided below, a brief introductory description will be provided here. - The
integrated circuit 230 provides the capability of driving up to eight segments or pixel electrodes with fouroutput driving circuits command decoder 231 contains the command shift register for clocking in a series of four possible commands and decoding these commands which are then provided through thecontrol bus 232 to thedrivers integrated circuit 230 depending on which direction the integrated circuit settles into a receiving substrate in the fluidic self-assembly process. If, for example, theintegrated circuit 230 settles into the receiving substrate such that the rotate Apad 240A receives a clock signal (see, for example,FIG. 3D ) then shiftbuffer 236A will cause an effective disconnect in thedata bus 233 between the data out port of thedriver circuit 235D and the data in port of thedriver circuit 235A. Further,pad 239A will become an input pad andpad 239B will become an output pad and pixel data or other data will get shifted intoinput pad 239A through the I/O controller 237A and through theshift buffer 236A and then through thecircuits O controller 237D and finally to theoutput pad 239D. This will allow the display driver, when theIC 230 is used as a display driver, to shift data from one display driver to another display driver, such as the embodiment shown inFIG. 3D . As will be described further below, each driver circuit, such asdriver circuit 235A, will receive after all data has been shifted through the appropriate display data which then can be used to update to the outputs which are coupled to the driver, such asoutputs command decoder 231 receives the various commands used to control the integrated circuit through theclock signal 279, which in one embodiment is also providing, as noted herein, a power voltage rail for the operation of other logic within theintegrated circuit 230. -
FIG. 4C is an enlarged version ofFIG. 4B showing much of the circuit shown inFIG. 4B . It will be appreciated that since theintegrated circuit 230 in one embodiment is externally functionally symmetric, the portion shown in FIG. 4C shows enough of a view ofFIG. 4B such that there is an adequate description of this circuit. Table A shows a description of each of the pads ofIC 230.TABLE A Pin/Pad Description Pin Type Description Clk Input Clock for data and command input, and digital power supply Vdh (X4) Power High voltage power supply Gnd (X4) Ground Analog and digital ground IA/OC Inout Four input/output data pins. One IB/OD configured as input, and one as IC/OA output by orientation pins. (all ID/OB LVIO pins have internal pull down resistors.) RotA Input Rotational orientation control RotB signals. Assertion of one signal RotC will select data input and output RotD pins Out1A Output High voltage outputs Out2A Out1B Out2B Out1C Out2C Out1D Out2D - One aspect of the
integrated circuit 230 will now be described by referring toFIGS. 5A, 5B , and 5C. This aspect relates to a circuit in which a power voltage rail signal is derived from another signal which in one embodiment is a clock signal. This power voltage rail signal is then used by other logic within the integrated circuit to derive power for the other logic. As shown inFIG. 5A , thesignal 250 may be a clock signal which has a regular duty phase which in this case is a 50% duty cycle. Thesignal 251 has a pulse nested within consecutive rising and falling edges of theclock signal 250 shown inFIG. 5A . That is, thepulse signal 251 rises only after the clock signal has settled in a high state and falls while theclock signal 250 is still within a high state. Thissignal 251 may be generated by a nestedpulse control logic 256 from thesignal 250. The nestedpulse control logic 256 generates at anoutput 257 thesignal 251 which is supplied to asampling circuit 258 as shown inFIG. 5B . Thesampling circuit 258 also receives theinput signal 255 which may be theclock signal 250. Thesampling circuit 258 generates a power supply signal which is stored in apower storage 259 which is then used to provide a powervoltage rail output 260.FIG. 5C shows one exemplary embodiment of the circuit shown inFIG. 5B . Theclock input 279 is supplied to a nestedpulse control circuit 275 which provides an output labeledclock subpulse 280 which is the same as thesignal 251 shown inFIG. 5A . Thisoutput 280 controls asampling circuit 276 which includes the transistor M2020 as shown inFIG. 5C . Thesignal 280 is supplied to the transistor M2020, which is a P channel transistor, through the inverters formed by transistors M2010 and M2011. The N channel device of this inverter, transistor M2011, is coupled toground 278. The power storage is formed by thestorage capacitors 277 which in one embodiment are twelve large field effect transistors wired as capacitors as shown inFIG. 5C . The voltage sampled from the high clock signal during the pulse is stored in these storage capacitors in order to provide the voltage Vdd which is labeled as 282. Thus, when the clock signal rises high, after a short period of time the transistor M2020 allows the high clock signal to be stored onto thestorage capacitors 277 and then after thepulse signal 251 falls back to a low state, theclock signal 279 is disconnected from the storage capacitors. This sequence is repeated for each clock cycle such that charge from the clock high signal during a portion of the time that the clock is high is stored onto thestorage capacitors 277 during the portion of the time that thepulse signal 251 is high, which only occurs during a portion of thetime 250A as shown inFIG. 5A when the clock signal is high.FIG. 5C also shows that theclock signal 279 is used to generate other signals including a clock R (ClkR) signal 401 (through a resistor). Thecircuit 234 shown inFIG. 5C includes various transistors which are either P channel FETs or N channel FETs. The width/length ratio for these transistors are shown inFIG. 5C .FIG. 5D shows thelength 291 relative to thewidth 292 for an FET device having a gate, source and drain, where the gate of theFET 290 is shown by a dashed line as slightly overlapping the source and drain regions of theFET 290. It will be appreciated that other ratios may be utilized depending upon the desired characteristics of the circuit. -
FIG. 6 shows the power onreset circuit 281 which receives the voltage rail input 282 (Vdd) and theclock signal 279 input and provides a power onreset output 283 through the circuitry shown inFIG. 6 . This circuit generates a short pulse (a high pulse) for a few microseconds if the clock signal comes up quickly and thereafter the power onreset signal 283 goes low and remains low. If the clock signal comes up slowly (rises slowly) the power on reset signal will go high for a few microseconds after Vdd has retained its normal operating value (e.g. 5 volts). The power on reset circuit ofFIG. 6 consists of a simple latch which is sized and capacitor coupled to force a consistent start up orientation. Upon application of the first rising edge of the clock signal, this circuit will assert until its own internal timing triggers the latch to flip, and this will deassert (drive low) theoutput signal 283. The internal timing of theoutput signal 283 varies with the Vdd voltage levels, but provides a consistent pulse for resetting internal circuit nodes which receive theoutput signal 283. -
FIG. 7A shows an example of a position detector circuit which in this case is the orient circuit such asorient circuit FIG. 7A receives theVdd input 282 andground 278 and also a rotate in (ROTIN)input signal 301. The rotate insignal 301 is coupled to the corresponding rotate or position detect pad such aspad 240A for the corresponding orient circuit as shown inFIG. 4B . The rotate out orROTOUT signal 302 provides the output from the orient circuit which is coupled to two I/O controllers as shown inFIG. 4B for the corresponding orient circuit. For example, if the orient circuit isorient circuit 238A, then the rotate outsignal 302 is coupled to the input enable input of the I/O controller 237A and to the output enable input of the I/O controller 237B. And in this instance, the rotate ininput 301 is coupled to the rotate Apad 240A. The inverse of the power on reset signal is received as theinput 283A and is coupled to a P channel device as shown inFIG. 7A . A latch formed byinverters output 302. When theintegrated circuit 230 is first powered up, all orient circuits provide a low or zero output, and then the one orient circuit which is coupled to the position detector pad which is coupled to receive the clock signal (see, for example, the rotate Apad 184A shown inFIG. 3D ) provides a high signal at theoutput 302 while the other orient circuits continue to provide a low signal at theoutput 302 of their circuits. In this manner, all four orient circuits shown inFIG. 4B cooperate together to provide a position detector which specifies the internal functionality of theintegrated circuit 230 depending upon the position detected by the position detector circuits. It can be seen that the orient circuit is disabled during a power up operation but subsequently one is enabled by the rising clock edge. Table B below shows the combinations which are possible for theintegrated circuit 230 depending upon the position detected by the position detector logic which consists of the fourorient circuits 238A through 238D.TABLE B Data Orientation Rotation signal asserted Input data pin Output data pin RotA IA/OC IB/OD RotB IB/OD IC/OA RotC IC/OA ID/OB RotD ID/OB IA/OC -
FIG. 7A shows one example of using position information specified by a receiving substrate to indicate to an integrated circuit which function or functions the circuit is to provide.FIG. 7B shows an alternative embodiment in which the translational position on a receivingsubstrate 305 specifies the functionality to be provided by the integrated circuit. As shown inFIG. 7B , the receivingsubstrate 305 includes asignal line 309 which is designed to connect to bonding pads on the integrated circuit deposited into the receiving substrate, which bonding pads are at the extreme corner of the integrated circuit.Signal line 308, on the other hand, is designed to be connected to the corresponding bonding pad which is next to the bonding pad at the corner as shown inFIG. 7B . Thus, theintegrated circuit 306, which can be deposited in any one of four rotational orientations into the receivingsubstrate 305, hasinterface pads 311 one of which will be coupled to asignal line 308 on the receivingsubstrate 305. This can be seen in the cross-sectional view ofFIG. 7C in which theIC 306 has been deposited into the receiving substrate 305 (e.g. such as through a fluidic self-assembly process) and then a metallization or otherconductive layer 308 is provided on top of theIC 306 and on top of thereceptor substrate 305 in order to make an electrical interconnect with thepad 311. This will cause the integrated circuit to perform a desired function in the position into which is has fallen while integratedcircuit 307 may perform a different function as specified by its position through thesignal line 309 which is coupled to thepads 312 at the extreme corners of the integrated circuit. Thus, the same integrated circuit may be fabricated in multiple instances and removed from a wafer and then dispersed over a receiving substrate in a fluidic self-assembly process and the various circuits will fall into different positions but provide different functions based upon those positions as indicated by the corresponding signal lines on the receiving substrate. As noted above, each integrated circuit may provide one function determined by its position or multiple functions determined by its position. Further, the position may select between one of two or more functions such that only that one function is performed. It will be appreciated that the signal lines, such assignal lines lines 309, a different set of functions may be provided. -
FIG. 8 shows an example of an I/O controller circuit such ascircuits FIG. 4B . This circuit enables bi-directional capability for the digital data path through theintegrated circuit 230. It includes input protection and output buffers capable of driving pads such aspads FIG. 8 represents any one of the I/O controllers 237A through 237D, the following description, for purposes of simplicity, will assume that the circuit ofFIG. 8 is the I/O controller 237A which is coupled to the I/O pad 239A and to theshift buffer circuit 236A as shown inFIG. 4B . Theinput 353 of the circuit ofFIG. 8 is the same as the input enable input of the I/O controller circuit 237A shown inFIG. 4B . Theinput 352 ofFIG. 8 is the same as the output enable input of the I/O controller 237A as shown inFIG. 4B .Internal node 348 ofFIG. 8 is the inverse of theinput signal 353.Internal node 349 ofFIG. 8 is the inverse of theinput signal 352. The circuit ofFIG. 8 is coupled toVdd 282 and is also coupled toground 278 as shown inFIG. 8 . Thepad 350 ofFIG. 8 is the same as the pad input or output of the I/O controller 237A, which pad input or output is coupled to theelectrical interface pad 239A as shown inFIG. 4B . Theoutput 354 of the circuit ofFIG. 8 is the same as the output which is labeled “input” of the I/O controller 237A shown inFIG. 4B . In other words, theoutput 354 fromFIG. 8 , when this circuit ofFIG. 8 is the I/O controller 237A, is coupled to the pad in input of theshift buffer 236A. The input 351 ofFIG. 8 is the same as the input which is labeled “output” of the I/O controller 237A. Again, assuming that the circuit ofFIG. 8 is for purposes of this description the I/O controller 237A, then if the input enable signal is asserted by the rotate A pad such that theinput 353 is high then the I/O controller provides a signal path from thepad 350 to theoutput 354, meaning that the I/O pad 239A is functioning as an input pad. On the other hand, if the output enableinput 352 is asserted, then the I/O controller is providing a signal path from the input 351 to thepad 350 such that the I/O pad 239A is functioning as an output pad. Each of the corresponding I/O controllers inputs pad 350 will be placed in a no-operation state when neitherinput FIG. 4B provide for configuring its corresponding I/O pad (e.g. one of 239A, 239B, 239C, and 239D) as an either input pad or an output pad or a no-operation pad. -
FIG. 9A will now be referred to in describing yet another aspect of the present invention which provides an efficient, low power pulsed level shifting circuit according to one exemplary embodiment of this aspect. This circuit receives a low voltage input and also receives a clocked pulse signal. The low input signal is applied to devices in a current mirror which is passing current through two current paths under control of the clocked pulse input. One of these current paths controls a node to change a state of a node which in turn drives a driver to a shifted voltage state relative to the input voltage state. This level shifting circuit is used within thedrivers - In one embodiment, the
circuit 359 includes an input to receive a clocked signal having a pulse during each clock cycle and a second input to receive a first voltage signal, such as a low voltage signal. A current mirror circuit is coupled to the first input and is also coupled to the second input, and the current mirror circuit controls a state of a node. An output driver is coupled to the node and the output driver shifts a voltage level from the first voltage signal to a second voltage signal when the node is in a first state. The current mirror includes a first current path and a second current path and a first control electrode, such as a gate electrode, which is coupled to the first current path. A second control electrode, such as a gate electrode, is coupled to the second current path and is coupled to the first control electrode. Typically, a transistor device which is a first transistor device in the first current path is substantially matched in size parameters to a second transistor device which is in the second current path. The pulse causes a current to flow in the second current path to set the node at the first state, and after the pulse, the node retains the first state with substantially no current flowing in the second current path. Thelevel shifting circuit 359 receives an input low voltage signal at itsinput 360 and also receives a clockedpulse signal 280. Further, thecircuit 359 receivesVdd 282 as shown inFIG. 9A and theground signal 278. A current mirror formed by N channel FETs M8 and M9 and M10 are coupled together atnode 363 which receives the output of a weak inverter formed by devices M10 and M15. M10 sets the current in M1 which determines a current in M2 and M8 and M9. M10 controls the current throughnode 363. The input to this inverter receives thepulsed clock signal 280, and this pulse controls the flow of current in the current mirror which charges anode 362. Thenode 362 controls the P channel FET M6 which controls the output of the state of theoutput 361. The current mirror circuit formed by the transistors M8 and M9 allows a communication between the low voltage section of the circuit and the high voltage section of the circuit without a large current consumption. Further, the pulses control the charging of thenode 362 such that current flowing in the current mirror is substantially off when thesignal 280 is low. An example ofsignal 280 is shown inFIG. 5A assignal 251. - Thus, the level shifter is driven in a pulsed manner with a periodic refreshing of the
node 362 which in turn generates the output signal atoutput 361. Theoutput 361 is driven to high which is a voltage derived from theVdh input 252. When theinput 360 is low the transistor M7 will be turned on, which will pull down theoutput 361 to substantially close toground 278. Thiscircuit 359 allows the control of a rail to rail high voltage signal (where the rail to rail transition is between Vdh and ground) using a much lower control voltage. Low power is consumed by modulating the current in the current mirror circuit by use of a very low duty cycle signal, in this case, theclock subpulse signal 280. The on and the off states of thelow voltage input 360 are passed to the transistor M6 in a momentary fashion, and these on and off states are held on the transistor gate of transistor M6 for most of the operating cycle with no current through the current mirrors, which include the first current path and the second current path formed by the devices M8 and M9. Transistors M3 through MS limit the gate/source voltage on M6 when switching M6 on. In an alternative embodiment, an additional device M16 may be coupled to M3 and to M1 to further reduce power consumption. M16 may be a P channel device (a P channel FET) having its gate coupled to the gate of M3 and having its source coupled to the source of M1 and its drain coupled to the drain of M1 and this device may be sized to be the same size as transistor M2. -
FIG. 10 shows an example of a driver circuit which may be used as thedriver circuits 235A through 235D ofFIG. 4B . Each driver circuit, such ascircuits 235A through 235D, includes a two bit shift register, two buffer latches 390 and 391, exclusive OR gating for output inversion under control of a polarity signal, and two highvoltage level shifters 359. The shift register timing is somewhat different from traditional shift registers in that due to power supply requirements, the data set up and hold times constitute most of the clock period, which creates a very small time in which the data can change. An internal delay in the shift buffer circuit (e.g. 236A-236D) prevents any race conditions which may occur in moving data from oneIC 230 which is functioning as a display driver to another IC in the shifting of data between IC to IC. The buffer registers formed bylatches latches level shifter circuits 359 convert the digital outputs to high voltage analog outputs to drive display segments such as pixel electrodes. - Each driver circuit, such as
circuit 235A, receives signals from thecontrol bus 232, such as the polarity signal or the reset signal. The reset signal is used to reset the pixels to a desired predetermined state and the polarity signal is used in those cases where the display media requires an inversion of the polarity of the signal over time (e.g. certain types of nematic liquid crystals require the polarity to be inverted over time as is well known in the art). The update signal from thecontrol bus 232 causes passgates latches latches outputs 241X. The polarity signal controls the output through thepass gates 392 as shown inFIG. 10 . The reset signal controls resetting of the state of the display pixels by activating theN channel FETs 388 to cause the inputs to thebuffers control bus 232 and are used to control shifting of data through the shift registerserial bus 233 internally within theIC 230. It will be appreciated that along at least a row of the display or a portion of the row of the display, multiple ICs such asICs 230 will be receiving these shift data and shift data bar commands to cause the pixel data to be shifted through multiple ICs along the row as well as internally within theIC 230. The input 371 (data in) corresponds to the data in input on each of thedrivers 235A through 235D. Theoutput 372 corresponds to the data out output of each of thedrivers 235A through 235D. It will be appreciated that buffer registers 381 and 382 are stages or elements within the shift register and these stages are separated by the pass gates such aspass gates Inverters FIG. 10 . -
FIG. 12A shows an example of a shift buffer circuit which may be used for each of theshift buffer circuits shift output 540 ofFIG. 12A is the same as the shift out output of eachshift buffer circuit 236A through 236D. The shift ininput 541 ofFIG. 12A is the same as the shift in input of eachshift buffer circuit 236A through 236D shown inFIG. 4B . Theinput 353A receives its signal from the input enable input of the I/O controller which is coupled to the corresponding shift buffer. For example, in the case of theshift buffer 236A ofFIG. 4B , theinput 353A is coupled to the input enable input of I/O controller 237A which is theinput 353 shown inFIG. 8 . Theinput 354A ofFIG. 12A is coupled to theoutput 354 of the I/O controller circuit shown inFIG. 8 .Internal node 353B ofFIG. 12A is derived from inverting the signal at theinput 353A. The shift buffer circuit ofFIG. 12A allows shifting through theserial bus 233 except for one point determined by the position detector logic which, as described above, electrically disconnects the serial ring formed initially by thebus 233. -
FIGS. 11A, 11B , 11C, 11D, and 11E will now be referred to in describing thecommand decoder circuit 231 as well as the overall operation of theintegrated circuit 230 when used as a display driver in a display such as the display shown inFIG. 3D . It will also be appreciated that theintegrated circuit 230 may be used in non-display systems or systems which are displays and input systems (e.g. touch screen input) such as thesystem 550 shown inFIG. 13A . Thecommand decoder circuit 231 includes a seven bit command shift register (formed bylatches inverter pairs 430,inverter pair 431,inverter pair 432, andinverter pair 433. Thecommand decoder circuit 231 also includes a clock pulse detection logic (timing discriminator 408) and register control logic such as the commanddecoder status register 407 and the command awake sequence generator. Thetiming discriminator 408 receives theclock R signal 401, which signal 401 is also used to generateinternal signals 403 and 403A which are used within thecommand decoder circuit 231. The clock subpulse signal 280 is used to generate twosignals command decoder circuit 231 as shown inFIG. 11A . For example, theNAND gate 415 receives thesignal 404 and also receives thesignal 409 which is the command clock enable signal from the command awake sequence generator. Normal duty cycle clock signals, such as those shown as 491 inFIG. 11B , maintain theclock data node 402 at a low state. A short clock pulse, such aspulse 492 shown inFIG. 11B , causes theclock data node 402 to generate a high signal which, as will be described below, causes the commanddecoder status register 407 to generate thesignals command decoder circuit 231. Thesignal 406 is applied as an input to the command awake sequence generator as shown inFIG. 11A to generate the command clock enablesignal 409 and the command shiftclear signal 410. The second NAND gate in the command awake sequence generator which generates thesignal 410 also receives the power onreset bar signal 283A. Theclock data node 402 is coupled to thepass gate 405 and is also coupled to the input of the command shift register, the first latch of which islatch 416. Conventional pass gates and inverters are used throughout the command shift register as shown inFIG. 11A to create a shift register. The last stage of the shift register is the stop bit latch formed by the pair ofinverters 423. The output of this stop bit latch provides asignal 411 which is inputted to the command decoderstatus register logic 407. The command clock enablesignal 409 is provided to one input of theNAND 415 and thesignal 404 is provided as the other input toNAND 415.P channel FET 447 receives thesignal 410 which is used to clear the command shift register at the beginning of an awakening of thecommand decoder circuit 231. Thissignal 410 is also coupled to the gates of theP channel FETs 440 through 446 to clear each of thelatches 416 though 422 such that their output states are low (zero). Passgates control bus 232 as shown inFIG. 11A . - The incoming clock has two states: (1) normal operation with a 50% duty cycle (see clock signal 491 shown in
FIG. 11B ), and (2) a command sequence operation with a 7% duty cycle (e.g. seepulse 492 shown inFIG. 11B ). Thetiming discriminator 408 detects the beginning of a command sequence by looking for the initial short clock pulse, such aspulse 492. The loading of a command into thecommand decoder circuit 231 is further shown inFIGS. 11B and 11D . Inoperation 501, thetiming discriminator 408 determines that it has received a short clock pulse and theclock data node 402 goes high, indicating the header bit of the command/instruction has been received. Inoperation 502, commandawake signal 406 goes high after the clock data signal 402 goes high and the command storage register (formed byinverter pairs 430 through 433) is disconnected from the command shift register (formed byinverter pairs 416 through 423). Thus the output commands stored in the command storage register are not affected by the new incoming command data stream. Then inoperation 503, old instruction data in the command shift register is cleared to low with the assertion of the command shiftclear bar signal 410. When the command shift bar signal goes low, then the command clock enablesignal 409 is asserted (by going high) and this allows the clock signal referred to as command clock (and its inverse, command clock bar) to be provided to the command shift register in order to clock the commands serially through the command shift register. It will be appreciated that thecommands 1 through 7 are loaded in reverse order as shown by the sequence 493 (shown inFIG. 11B ) which represents thecommand loading sequence 490. Every clock cycle generated through theNAND gate 415 shifts instruction bits through the command shift register from left to right as shown inFIG. 11A . A short clock pulse at theclock data node 402 which represents the input to the command shift register represents a 1 or high bit and a long clock pulse bit represents a low or 0 bit. Thus,command 6 shown inFIG. 11B is low whilecommand 2 shown inFIG. 11B is high. Inoperation 505, theinitial start pulse 492 is a header bit which reaches the last stage (inverter pair 423) causing the stop bit signal to be asserted which stops the shifting by deasserting the command clock enablesignal 409, and the commandawake signal 406 goes low causing the command shift register to update the command storage register. Then normal execution follows as shown byphase 494 inFIG. 11B . Typically, this normal phase involves data loading and the display of data as shown inFIG. 11C . Tables C and D below show the various commands according to one embodiment of the present invention and the functions provided by these commands.TABLE C Command Code Sequence Command # Programmed in sequence Command 1 Load 2 Update 3 Polarity 4 Reset 5 Unused 6 Unused 7 Unused
Note:
Command data is loaded serially fromcommand # 7 down tocommand # 1.
-
TABLE D Command Code Load Update Invert Reset Function 0 0 0 0 *** 0 0 0 1 *** 0 0 1 0 *** 0 0 1 1 *** 0 1 0 0 Data is loaded into data shift registers 0 1 0 1 Outputs are reset to zero state while loading data shift register 0 1 1 0 Current outputs are inverted while loading data shift register 0 1 1 1 All Outputs set high while data is loaded into data shift register 1 0 0 0 Outputs are latched with current data 1 0 0 1 ** 1 0 1 0 Outputs will be refreshed with current data and inverted 1 0 1 1 ** 1 1 0 0 No Changes 1 1 0 1 Outputs are reset to zero state 1 1 1 0 Outputs are complimented 1 1 1 1 All outputs will be set high
** This command sequence would clear and load data simultaneously, resulting in incorrect display data. This is also a high power condition in the output driver.
*** Loading data while updating display would cause the display to temporarily display the incorrect data.
- The four possible commands used in the output drivers (e.g. 235A-235D) are:
-
- 1. load/idle—(active low). When low, this command allows a pulsed version of the incoming clock to pass to the output data shift registers and clocks in serial data on the rising edge.
- 2. update/freeze—(active low). When low, this command allows the data loaded in the output shift registers to be latched into the buffer register. This register is directly connected to the inverter and high voltage output level shifters.
- 3. polarity (+/−). The polarity command allows all the outputs to be inverted to facilitate driving the display segments symmetrically.
- 4. reset. When asserted, this command will clear all contents of the data buffer registers without affecting the data loaded in the output shift registers of the drivers, such as
display driver circuit 235A.
-
FIG. 11E shows one exemplary method of operating a display which uses a plurality ofintegrated circuits 230 such as the arrangement shown inFIG. 3D . In the exemplary method shown inFIG. 11E ,operation 520 begins with a power up reset which places the display drivers in a default state in which display data is shifted into the display drivers, each of which include the shift register storage elements within the driver circuits, such asdriver circuits 235A through 235D. Inoperation 521, data is shifted in and as it is shifted in, it is displayed. Alternatively, the pixels can be set in a cleared state so that the display is blank or a homogeneous appearance until all data has been shifted in. After all data has been shifted in, inoperation 522 the display may be manipulated or controlled with commands to the decoders in the display drivers. For example, the display may be reset again to clear the display or the polarity may be changed in those instances where this is required or new data may be loaded for a new image to be displayed by setting update to low and loading the new data and then setting update to high to display the new data. -
FIG. 13A shows the interconnection of twointegrated circuits 230 according to one exemplary embodiment of the present invention. As noted above, the clock and data signals are bussed substantially along only one axis of the display. Further, there is no physical crossing over of the interconnections on the receiving substrate which holds theintegrated circuits 230. -
FIGS. 14A, 14B , 14C, and 14D indicate an alternative embodiment of anintegrated circuit 560 which is similar tointegrated circuit 230 except it is less complex as can be seen from these figures. Many of the same components/circuits in theintegrated circuit 230 are also used in theintegrated circuit 560. However, thecommand decoder circuit 231 is replaced bycontrol circuit 561 which includes asimplified control bus 575. This integrated circuit receives aclock signal 568, aVdd signal 566, and aground signal 567. This integrated circuit is capable of driving four outputs but does include configurable I/O pads such as thepads 239A through 239D. Thisintegrated circuit 560 also includes position detecting logic shown ascircuits 563A through 563D. Thedriver circuits 562A through 562D are simplified and are shown inFIG. 14B . The position detection circuits are also simplified and shown inFIG. 14C . Theintegrated circuit 560 can be coupled together with other similar integrated circuits in the manner shown inFIG. 14D to form a display driver or other types of devices. In one embodiment, the display driver shifts data horizontally or vertically along substantially one axis of the display. -
FIG. 15A shows an example of one particular embodiment of a display device using theintegrated circuit 230. This display device may, in one embodiment, be a flexible display for use in a smart card type credit card. In the example shown inFIG. 15A , a single layer of conductive interconnect, in this case a metal interconnect, is used to interconnect the pixel electrodes and theintegrated circuits 230 without requiring another layer of interconnect and an intervening insulating layer, thus greatly simplifying a roll to roll/web process for manufacturing a flexible display. According to one process for manufacturing this smart card display, a receiving substrate is a flexible plastic material into which holes are formed for the openings for theintegrated circuits 230. The flexible receiving substrate is strung from one roll (e.g. a beginning roll) to another roll (e.g. an ending roll) and is moved through rollers in a process which includes a fluidic self-assembly process for causing theintegrated circuits 230 to be deposited into openings in the flexible receiving substrate. Then an interconnect layer, which may be a separate flexible material also manufactured in a roll to roll/web process, may be applied to the receiving substrate after theintegrated circuits 230 have been deposited into the openings. This will form the interconnect of the display device, allowing it to function with multiple pixel electrodes and multipleintegrated circuits 230. The use of only a single electrically conductive interconnect layer to form the electrical connections between pixel electrodes and display drivers greatly reduces the manufacturing complexity and cost. No insulating layer to separate stacked electrical interconnect layers is needed and no alignment to vias in this insulating layer is needed.FIG. 15B shows an enlarged view ofFIG. 15A so that the conductive lines can be more easily seen. The embodiment ofFIG. 15A is similar to the embodiments shown inFIGS. 2C and 3C . - In the foregoing specification, the invention has been described with reference to specific exemplary embodiments thereof. It will be evident that various modifications may be made thereto without departing from the broader spirit and scope of the invention as set forth in the following claims. The specification and drawings are, accordingly, to be regarded in an illustrative sense rather than a restrictive sense.
Claims (77)
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Also Published As
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AU2001293205A1 (en) | 2002-04-08 |
WO2002027701A3 (en) | 2003-01-09 |
WO2002027701A2 (en) | 2002-04-04 |
US6980184B1 (en) | 2005-12-27 |
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