CA1254624A - Dual mode laser printer - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
A dual mode laser printer utilizes a program-controlled microprocessor to switch between a high resolution, slow speed mode and a low resolution, high speed mode. In the printer a laser beam is modulated at a rate which is a first division of a system clock rate. This beam is caused to focus on a recording medium and, due to a rotating multi-faceted polygon, the beam sweeps across the medium. The medium is moved according to a second division of the system clock. By means of the microprocessor, the printer can be in either: (1) the high resolution mode in which the laser beam is modulated at a high rate due to the first divided signal and the medium moves at a slow rate due to the second divided signal, or (2) the low resolution mode in which the light beam is modulated at a lower rate due to the first divided signal and the medium moves at a faster rate due to the second divided signal.

Description

~13d2/A1(112684 1~54fi2~ 2273/02577 l D~AL MODE LASER PRINTER

Thi6 lnvention relate~ to la~er printer~ and, ~ore part~cularly, to b~gh resolution or typographical qual~ty l~er 6 prin~ers~
In recent ye~r6, l~ser pr~nters h~e ~een util~ed ln ~n~reasing nuFber6 a~ ~ ~eans for producing h~rd copy frcm a computer, computer generated ~ideo or video source. ~he ~re advanced of these l~er printers produce the hard copy with 10 g~od resolution ln relatively short period of tlme.
B~si~ally, a laser printer u~e~ nn opti~al lens system to fo~u6 the light beam output of a laser to ~ ~pot on a photo~ensitive ~urface. The ~pot i~ cau6ed to s~eep across the 6urace in D ra~ter fashion by ~ rot~ting or oscillating ~irror. Computer or video raster informat~on ~odulates the light beam a~ the photosensitiv~ surface ves in a direction perpendicular to and under the sweep~ng li~ht beam. If the photosensitive ~urface i8 the photoconductor drum in an electrophotographic process, the sweeping ~nd modulated light beam causes the formation of an electro~tatic charge image on the drum. Thi6 image can then be developed, transferred to paper and fused ~ith the paper in a ~anner typical of electrophotographic copiers. An example of ~uch a laser printer is aisclosed in U.S. Patent ~o. 3,867,571 of Starkweather, et ~l.
Laser printers typically have resolutions of about

2~0 dot~/inch and mo~t have resolutions under 400 dots/~nch.
Thus, they are generally limited to computer data output and general office use. In the printing and publishing industries, resolutions in e~cesfi ~f 500 dots/inch are used. To achieve i4ÇiZ~

l this resolution, electronic phototypesetters are generally used. An example of these devices is the Monotype Lasercomp manufactured by Honotype Corporation, Ltd. of Salfords, Redhill, England. Such phototypesetters use focused light, e.g. from a laser beam, to expose a photographic film medium and generally function like the system described in U.S. Patent ~o. 4,257,053 of Gilbreath.
The difficulty with the electronic phototypsetters that expose film is that they are relatively slow, film is relatively expensîve (well over 10 times the cost of paper and toner) and generally requires inconvenient, time-consuming chemical development.
There is a need in the publishing and printing indus-try for a device with the time, cost and convenience benefits of a laser printer and with ~ufficient resolution that it can be used to produce: (1) typographic page proofs of the image information which is intended to produce a copy or master from a phototypesetter; (2) direct output of typographic quality documents, i.e. demand printing; and (3) typographic quality masters for volume duplication. In order to achieve this, the resolution of laser printers must be significantly increased, without substantial sacrifice in the cost of the system.
In addition to having a laser printer with high resolution and reasonably good speed, it would also be desirable to have a laser printer which can switch between this high resolution mode and a low resolution mode in which the high speeds of typical laser printers are available. However, such a mode switch should be easy to perform and should be accom-plished relatively quickly.

54~

Summary_of the Inventlon The present invention is directed to the develop-ment of low cost laser printers that can be switched between at least one high resolution/moderate speed mode and another low resolution/high speed mode. The high resolution is achieved by an optical system that keeps the laser light spot in focus as it sweeps across a photo-conductor medium, despite errors in a rotating polygon that creates the sweep of the beam. In addition, electronic circuit means are provided for correcting scan velocity errors without the use of expensive optics. In order to prevent a loss of resolution in the electrophotographic process, the motion of the photoconductor medium and the hard copy paper are accurately positioned through the use of precision stepper motors which are driven by a system clock that also synchronizes the video data rate. Further, the change can be made quickly without having to wait for the rotating polygon to change speed by keeping its speed constant and changing the number of facets used. Thus a change from a high resolution mode to low resolution mode is achieved under control from the program of a micro-processor by changing ~l) the speed of the stepper motors, (2) the heat of the fuser and corona current in the electrophotographic process, (3) the laser output power and (4) the number of facets of the rotating polygon that are used.
In accordance with an aspect of the invention there is provided a laser printer system having at least two operating modes, said modes differing from each other in terms of resolution and speed such that the higher the resolution the lower the speed, comprising a photosensitive ~s~
medium; means for generating a modulated beam of laser light focused onto said medium; at least one moving mirror surface located in the path of said focused light beam before said medium for reflecting the beam such that it sweeps across the medium; detector means for detecting the start of sweep of the beam across the medium and producing a start of line signal; clock means for producing a plurality of related clock signals; photosensitive medium motor means for moving said photosensitive medium at a ].0 rate determined by a first one of said plurality of clock signals; and control means for controlling the modulation of said laser beam according to a second one of said plurality of clock signals and the start of line signal, said control means causing the printer to operate in at least (1) a high resolution mode wherein the light beam is modulated at a high rate determined by the second clock signal during fewer than every scan by the moving mirror surface and the first clock signal causes the medium to move at a slow speed, and (2) a low resolution mode wherein the light beam is modulated at a lower rate by the second clock signal during a greater number of scans by the moving mirror surface than the higher resolution mode and the first clock signal causes the medium to move at a faster speed.
In an illustrative embodiment of the invention, the output of a video modulated solid state laser is turned into a scanning spot on a photoconductor drum of an electrophotographic process via an optical system that includes a rotating polygon. The laser beam is directed through a collimator so that its rays are parallel. This collimated beam is then passed through a -3a-I,I ZS~t~

first ~:ylindrical len6 that ~ocuses the beam in the vertical or cross-scan direction ~ust prior to the ~cets of the rotating polygon. Due to the noving facets of the polygon, the beam is c~Aused to sweep acro6s the input of a scan lens assembly. In 6 ~he high resolution ~ode, every other facet i6 used for scanning ~o as to naintain synchronism between the 6pecified ~nput data rate and the print$ng rate. In the low resolut~on ~ode the system ~icroprocessor causes every facet to be u6ed to provide the appropriate ~y6tem data rates. Thu6 the polygon speed is 10 kept the same in both ~ades.

Regardles6 of the mode, i.e. high or low resolution, the scan lens a~sembly focuses the beam in the horizontal or scan direction along a straight line coincident with the photocon-ductor, i.e. it produces horizontal focusing and field flattening.
1~ Also, a 6econd cylindrical lens after the scan lens assembly in conjunction with the scan lens assembly refocuses the beam in the vertical or cross-~can direction.
8y placing the first and 6econd cylindrical lenses and scan lens on the optical center, errors in the manufacture of the polygon can be ~inimized. Therefore, the polygon can be made with less strict tolerances and, consequently, at a lower cost, without degrading the 6ystem resolution.
Because the ~can lens assembly acts as a field flattener, it introduces a scan velocity error, i.e. the speed at which the focused spot travels across the photoconductor varies. This could be corrected with further optical elements, but it has been found that it is ~ore economical to correct this electron-ically. In acco~pli6hing this, the video raster data for one line is 6tored. It is then read out and used to ~odulate the laser ~hen a ~6tart-of-scan~ photodetector indicates that the 1 laser is ~bout to sweep across the photoconductor drum. The clock signal for reading the data from memory~ however, is varied in an analog sinusoidal manner that is opposite to the ~can velocity error. This analog variation is stored in a 6 read-only memory and the result is to match the data read out to the laser with the fipOt sweep ~peed EO as to eliminate the scan ~peed error.
High resolution requires not only an accurately ~weeping focused spot, it requires accurate movement of the photoconductor drum upon which the spot writes to form an electrostatic image and the accurate movement of the paper onto which the developed image is transferred. This is accomplished by rotating the photoconductor drum and the paper feed mechanism via stepper motors having several hundred poles. The 6 ignal for 16 these stepper motors is derived from a system clock which also drives the polygon and controls the readout of data to the laser. In addition, an encoder is located on the photoconductor drum so that its position may be known within a few degrees of rotation. The system control microprocessor uses the drum position information along with the other system parmeters to control the entire system and to maintain resolution in the vertical or drum movement direction.
At the command of the operator, the 6ystem will switch from a mode with high resolution, i.e. in excess of S00 dots/inch, and moderate speed, i.e. about 4 pages/minute, to a different mode with lower resolution, i.e. under 400 dots/inch, and high speed, about 16 pages/minute. Under program control in the high resolution mode the system is rapidly 6et up for producing copy at the high resolution mode by sending a lower clock rate to the stepper motors so the paper moves slower and 2~

1 the photoconductor drum ~urns ~lower. Also, la~er power i6 reduced, fuser heater temperature is reduced and corona cur-rents are reduced. These changes are made to compen~ate for ehe fact that the paper and drum are moving ~lower in the high resolution mode.
In order to allow mode changes to occur rapidly, it ~8 desirable to keep the polygon rotating at the same speed because it has a good deal of inertia and must be at the cor-rect Epeed. Further it is desirable to keep constant the data transfer rate to the printer so that the interface cir-cuitry and the video source need not be changed. Both of these goals are achieved by using only every other facet of the polygon in the high resolution mode. This allows time for the additional data for the high resolution image to be sent to the 16 printer at the low resolution rate and accumulated in the system memory. Thus, the laser is modulated at a higher rate during a sweep in the high resolution mode than in the low resolution mode to produce higher horizontal resolution. Also, since the photoconductor drum is turning slower, the raster lines are closer together and there is a higher vertical resolution.
In switching to the lower resolution mode, the motors are moved faster 80 the vertical resolution is reduced and the laser is modulated slower so the horizontal resolution i5 lower. Since there is less information to be recorded, there i5 2~ no need to wait for it and scanning can be accomplished using each facet.
Brief Description of the Drawin~
The foregoing and other features of the present invention will be more readily apparent from the following detailed description and drawings of an illustrative embodiment of the invention in which:

~'~5~

1 Fig. 1 is ~ block diagram of ~ laser printer according to the pre~ent invention:
Fig. 2 is ~ ~chemaSic diagram of the scan speed cor-rection and data handler circuit~5 Fig. 3 is a 6che~atic of the laser drive c~rcults;
Pigs. ~A, 4~ Dnd 4C are ~chematic diagra~s of the circuits for driving the polygon, photoconductor drum, and paper feed ootors, respectively;

Fig. 5 is a ~chematlc dia~ram of the microprocessor 10 that controls the overal operatlon of the system; and Fig. 6 is a flow chart for the ~icroprocessor of Fig. 5.
Description of an Illustrative em odiment In Fig. 1 there is shown a block diagram of a la~er printer according to the present invention. This printer is used to make a copy on plain paper of an image created by a raster image processor (RIP) ~uch as a high-speed digital phototypesetter 50. An example of such a device is the Monotype Lasercomp manufactured by ~onotype Corporation, Ltd. of Salfords, Redhill, England as models MK2 and MK2i. Sowever, the present invention can be ad~pted ~o print an image from any device capable of creating digltal raster scan data directly or from a storage medium.

The present laser printer includes a laser diode 10 which i~ enabled at appropriate times by the system controller and modulated by data derived from output logic circuit 78 ~.e. microprocessor 80 through the laser driver circuit 90, whenever the machine i6 turned onO At the same time a system clock 71 has it6 output divided in timer/divider circuit 73 to produce a drive signal for a mo~or and control unit 11 that spins a polygon t3 that has reflecting facets 15. The polygon motor is a ~our pole hysterisis synchronous motor. Its controls circuit is shown in Fig. 4A.
In Fig. 4A a divided clock signal from timer 73 is applied directly to an H-bridge control circuit 412, a 94-phase shift circuit 414 and a first pulse-width ~odulator - H
bridge circuit 416. In addition, the output of pha~e-~hift circuit 4t4 is ~pplied to control 412, and to a second pulse-width modulator - H bridge circuit 418. The two modulator circuits 416,418 operate under control of circuit 412 and determine the direction of current flow. These modulator circuits in turn produce the drive signal for polygon motor 11 via power amplifiers 415, 417 whose output currents flow through the pole windings of motor 11 such as to cause it to 16 rotate. In the present preferred embodiment, the polygon has (ten) 10 facets and rotates at about 6000 rpm.
With the laser being modulated and the polyqon rotating, light passes through the'optics. In particular, the light beam from the laser 10 passes through a collimator lens system 12 and a cylindrical lens 14. It is then reflected from a steering mirror 16 onto the rotating facets 15 of the polygon 13. Because of the rotation of the polygon, the reflected light sweeps across a scan lens assembly 18 and a second cylindrical lens 19. By means of fold mirrors 20, 21 and 23 the light is directed onto electrophotographic drum 30. However, a portion of the light beam from mirror 23, or an adjacent smaller ~start-of-line" mirror 23', is directed to a start of line sensor 22.
The sensor converts the light into an electrical signal (nSOL~) which is supplied to microprocessor B0. The rate at which this sensor 22 generates SOL pulses in response to the sweep of the 5~6~
-1 light beam i6 directly related to the polygon ~peed, i.e. one per facet. Consequently the SOL ~ignal can be used by the ~icroprocessor 80 to a~sure that the laser diode is on and the polygon i8 Up to speed. Additionaly the SOL ~ignal indi-6 cates the start of a fican line ~o it provides ~nformation onthe physical pcsition of the polygon.
The Rlectrophotographic ~ystem utilized in the present design i~ generally referred to ~s the ~Canon~ proce~s, but other processes, e.g. the ~Xerox~ process, could also be u3ed. The difference between the ~Canon~ process and the ~Xerox~ process is that the ~Xerox~ proces~ involves imaging directly on a photo-conductor, while the ~Canon~ process uses a dielectric layer over a rectifier-type photoconductor. Other types of photoconductors can be used, but the rectifier type ls preferredO ~oth processes 16 are available commercially and are described ln the literature.
Only the modifications described below, are needed to adapt an electrophographic process to practice the present invention~
In a typical ~Canon~ process the photoconductor is mounted on a drum 30, iE made of cadmium sulfide, and has a die~ectric coating, typically Mylar. A drum heater 25 is used to improve the efficiency of the photoconductor-dielectric {maging medium prior to the start of operation.
Dur$ng ~tart up, the drum i B also rotated to make sure it is clean before writing i 6 commenced. This is achieved 2~ by flooding the entire photoconductor drum 30 with light from an erase lamp 27 wh$1e ~ second corona 38 ~s supplied with cur-rent from corona supply 32. The effect of this is to el$minate charge on the drum. This initial exposure $s al60 a preparation 5tep designed to ~wake up~ or sensitize the photoconductor.

* - Trade Mark _g_ ~ s~

1 Rotation of the drum 30 is by means of precision stepper motor and control 37. In particular, the drum motor is a 500 pole stepper motor with a gear reduction. Because of the large number of poles, accurate positioning of the drum, which ~aintains high resolution, i8 echieved.
The control circuit for the ~tepper motor i~ ~hown in Fig. ~B. This circuit contains five (5) current driver ~witches 430 which are operated in the proper sequence by a program stored in memory 432. A divided clock signal from timer/divider 73 is used to operate an address control circuit 434 for the memory 432. An input e from the microprocessor 80 via I/O decoder 242 (Fig. 2) can be directed to the address control in order to enable the address controller and bring it in se~uence with the rest of the system. Because of the high number of poles, the drum motor operates smoothly an accurately to position the drum.
Once the system is ready the microprocessor 80 super-vises all control of the system. ~n the present invention, this microprocessor is really a state controller and does not really process data. As one of its first tasks, the micro-processor authorizes the interface circuit 60 to allow RIP data from rasters image processor 50 be input to one of two memory circuits 72, 74. At an appropriate point in time after the start of the sweep of the laser beam across the drum 30, as indicated by the SOL signal, and related to the particular area on the drum where the information i5 to be written, the micro-processor allows data bits from one of the memory circuits to pass through OR-gate 76 and output logic 78 to laser driver circuit 90~
Laser driver circuit 90 which is shown in detail in Fig. 3 receives the signal from circuit 78 and uses it 1 to modulate the power to the laser diode, essenti~lly turning the laser on and off a~ a function of the ~nes a~d zeroes of the data bits which relate to the ~pots or picture elements ~pels) that will be imaged.
6 In the particular configuration illustrated, the printer writes the bac~ground, i.e. the laser is turned on ~or the white background areas on the ~opy and is off in the areas where there is an image. Thus, the laser light erases the background areas and leaves the black image areas behind. However the opposite system can also be used where the laser writes or is on in the areas needed for the image.
~ he modulated light beam coming out of the laser diode 10 has a unique characteri~tic. It diverges differ-ently in two different directions and it is essentially coherent light. Since the light diverges differently indifferent directions, it is necessary to modify it to obtain an appropriately shaped and focused spot on the photocon-ductor. To accomplish this collimator 12 is located after the diode. The collimator has a lens design which gives the specific output spot that is needed. In particular the col-limator 12 is a multiple lens system that reforms the spot in both directions into an essentially round beam with parallel rays.
Given the amount of distance available in the printer from the drum 30 to the collimator 12 and the desired focused spot size on the drum, it is possible to work backwards to determine the beam size from the collimator. Further, the distance between the collimator 12 and the laser diode 10 can be adjusted to get that size for a particular output size from the laser diode-1 At the end of the collimator there is a cylindricallens 14 which takes the beam and focuses it in the vertical, i.e. cross scan or ~agittal direction. This is done so that in the vertical direction the beam comes to essential focus before, but close to, the polygon 13. As ~ result the beam spreads over ~ larger area on the polygon f~cet than would a beam in focus on the facet. This tends ~o average out facet surface imperfections.

The beam, which is now expanding in the vertical direction, leaves the polygon facet, passes through scan lens assembly 18 and reaches a second cylindrical lens 19 placed at the end of the scan lens assembly 18. This reflected beam, even if it has been tilted or shifted because of the variations in the polygon faces, will basically refocus a second time at an equiva-16 lent distance from the polygon if the second cylindrical lense isaccurately positioned in the same plane as the first. Consequently, as a result of the two cylindrial lenses 14,19, any of the pyramidal manufacturing errors of t'he polygon in the vertical direction (due to either wobble or tilt) are essentially elimi-nated because the focused spot near the polygon face is reproduced in space in the same plane, even though it may have been high or low on the polygon face or reflected at a slightly varying tilt angle. Therefore, the need for a precision polygon is reduced by using these simple cylindrical lenses and this reduction in the polygon tolerances leads directly to a reduction in the cost of the polygon.
After the first cylindrical lens 14, the beam in the horizontal or scan direction i6 a collimated beam of a given size, not a focused beam as in the vertical direction. The size is specifically determined by the desired spot size when l the beam ~s focused on the photoconductor drum 30 and can be determined by simple coherent optics analysis. The ~pot is made relatively large because in coherent optics, the larger the collimated beam the finer the spot it can be focused to.
6 In the present optical system there is incorpor-Hted a steering ~irror 16 for alignment purpOSeE. This i~
done 80 that the optical assembly after the collimator 12 can be removed as a unit and aligned. ~owever, this mirror alignment is not required, it is just an advantage in terms of production. From mirror 16, the beam which is converging to focus in the vertical direction and collimated in the horizontal direction, strikes one of the moving facets 15 of polygon 13.
The reflecting facet of the polygon is not only 16 moving, its distance from the steering mirror is changing during each sweep. However, this does not cause a problem because the beam is a collimated beam in the horizontal direc-tion. In the vertical direction, this motion does have some effect because the focal distance is changing slightly. In particular the vertical size of the beam on the polygon is changing because of the changing distance from the focal point.
This effect, however, is taken care of in the scan lens assembly 18.
As the beam sweeps acros~ the scan lens assembly 2~ the scan lens performs two functions. One function is to focus the collimated beam in the horizontal direction down to a given spot size at the focal plane on the photoconductor drum 30. Its second function is to flatten out the line of focus.

Because of the sweep of the polygon the natural line of focus would be an arc. However, the photoconductor along the scan ~;~s~

1 line is flat. Therefore, a correction i6 made in the ~can lens assembly 18 to keep the spGt in focus across the photoconductor~
Therefore~ the ~can lens assem~ly is a field flattener and a focusing lens at the ~ame time.
It is quite expensive to make a perfect field flattener, 80 thi~ lens system does not give a perfectly flat focus line. Instead it produces a ~inusoidal line of focus that i8 correct at the beginning and end of the ~can line as ~ell as at the two points which are one-third of the distance after the beginning and before the end of the scan line. As a result, the line of focus is a little above the photoconductor in the first and last thirds of the scan and a little below on the middle third of the scan. Nevertheless, the focus remains sharp enough across the scan to provide resolution in excess of 500 dots/inch.
The field flattening, which changes the line of focus from an arc to a substantially straight line, causes a sinu-soidal variation in the velocity o~ the spot along the scan line~ Thi~ variation is known as "scan velocity or speed"

error. Such a scan velocity error can be corrected in the optics, but to do so is expensive. Rather than make a 6can velocity correction, the system allows the optical variation and corrects for it electronically by changing the pel data rate.

26 Since the scan velocity or speed error is constant, it is corrected by the scan modulator circuit 75 which varies the clock rate for ~ending data to the laser driver in a sinusoidal pattern stored in a memory 210. The details of this circuit are shown in Fig. 2. Because of scan modulator 75, the data handler circuit clocks out the data from memories ~25~

72,74 to the laser driver at a rate that varies in direct opposition to the scan velocity error ~o that data is recorded on the photoconductor ~t ~hat appears to be a constant velocity.
Within scan lens assembly there is a beam which 6 i8 being brought into focus in the horizontal or 6can direction and ~expanding in the vertical direction. At the end of the ~can lens assembly there i5 the second cylindrical len 19 ~hich refocuses the beam again in the vertical direction and in the same focal line a the focus in the horizontal direction.
The rest is of the optical system is basically a straight path down to the photoconductor drum 30. Folding mirrors 20, 21 and 23 along that route are merely used to fold the optical path so that it can f~t in a reasonably small package.
A part of the beam that comes off mirrors 23 or 23' hits the start-of-line sensor 22. Instead of using a mirror for this purpose, the start-of-line detector can be positioned next to mirror 17 so that it receives light directly from mirror 21. Whichever system is us~d, the light beam in strik-ing the start-of-line detector 22, informs the system micro-processor of the scan beam position on the rotation of eachfacet of the polygon.
The start-of-line detector may be a single photodiode circuit or a more complicated, but more accurate circuit~ In order to accurately detect the presence of the SOL signal, the output of the start-of-line sensor 22 is sampled at a very high clock rate. The rate is about eight ~8) times the picture element (pel) clock rate 60 the system can determine the light beam position to much less than a picture element. Therefore, the location of the start of line is determined precisely and repetitively from line-to line.

1 Once start of line is found, the system counts off a programmable number of clock periods to ~etermine where the start of data should be. This will be some location on the photoconductor and can vary from user to user, depending on where the user wants to s~art imaging on the drum.
As the ~canning and ~odulated laser beam co~es down onto the photoconduction drum 20, it passes inside or through a window in second corona 38. From this point on the raster light image created by the modulated and sweeping laser beam i6 devel-oped into an image on paper by the electrophotographic process.
In the present example, a basic positive chargelayer is put do~n on the dielectric layer by a first corona 36 as the drum 3~ rotates. The charge could also be negative.
Then the portion of the photoconductor with the charged dielec-tric over it is brought around under the opposite or negativepolarity second corona 38. While the opposing charge is being generated, the photoconductor i6 imaged or exposed to the raster sweeping, modulated light beam. The result is that the second corona neutralizes some of the charge from the first corona. It does this even if there is no light, but not to the same extent.
When the light beam hits the drum under the second corona 38, the photoconductor layer underneath the dielectric becomes conductive. Consequently, charges move to try to 26 neutralize the charge that is on the photoconductor layer.
Therefore, in the dark areas the first charge is reduced to a certain level and in the light areas the charge u~
reduced to zero or even reversed. The result is a pattern of different voltage or charge levels on the surface of the dielectric which forms a latent electrostatic image.

1 Once the latent electrostatic image is formed on the dielectric under the second corona, there are also a lot of electrons and holes free in the photoconductor. To remove them, the entire area i8 exposed with light by post exposure 6 lamp 29. This does not Affect the charge on the ~urface of the dielectric, because there is nothing to address it; but, it does cause recombînations of the holes and electrons in the photoconductor. Additionally, it ensures that all of the photoconductor is active and establishes a higher differential in charge between the surface of the dielectric and ground.
The differential charge levels forming an image on the photoconductor dielectric surface are rotated past a magnetic brush developer 35 with a reservoir that holds a toner material, ~ixed with a carrier material, which toner is attracted to the charge. Such two-component developer materials are commercially available. It is also possible to use monocomponent developer, i.e. ~here a magnetic toner is used alone.
Whatever developer is used, the material is attracted to a magnetic drum 35'. The shell of the drum is moved by motor and control unit 40. This causes the magnetic developer particles in the reservoir of the unit to form a brush-like tuft or covering on drum 35'. At the bottom edge of the reservoir there is a doctor blade that knocks off some of the particles to form a uniform layer of material that is brushed against the photoconductor drum while moving in the opposite direction from the photoconductor drum. An auger wheel 35'' driven by the developer drum 35' assures that the developer has a uniform consistency. When the layer of developer passes over the electrostatic image on the photoconductor drum, the toner ~25~

1 is attracted to the positive areas left on the drum and is repulsed by the negative area~ so that a toned or developed image remains on the dielectric.
As the toned image is moved around to a transfer corona ~2, paper or to some other media, such as Mylar, i~
brought into the ~achine under the control of microprocessor 80 at the proper time in the rotation of the drum 30. ~o ~ense the drum position an optical encoder wheel 39l is located on the drum and a detector 39 produces output pulses at every 2 of rotation and a TOP or ~top-of-page~ signal for the position or positions on the drum where printing is to occur.
All motion along the paper path is controlled by motor and control unit 40 which is tied to the various elements by chains or other means. The motor 40 is a precision stepper motor with 500 poles, so it essentially functions like a synchronous motor driven from the system clock. The circuit for driving paper path motor is a sequential current driver and it is shown in Fig. 4C. It is basically the same as the circuit for driving the drum motor shown in Fig. ~B. In particular, the windings of the 5-phase, precision ~tepper motor for the paper path are driven by circuit driver switches 440 according to a sequence for the 5 phases stored in memory 442. This memory is addressed by an address control circuit 444 that receives system clock impulses. Additionally, the 2~ address control circuit can be kept in synchronism with the rest of the system by an enable input e.
Since the motor drives for the drum and paper path are similar and are driven by a divided signal from the ~ystem clock, the paper can be made to move at approximately the same rate or linear speed that the photoconductor drum is moved, ~:~5~

1 e.g. about 0.6 inches per second in the high resolution de, i.e. at the low speed. The 6peed can be increased and the ~nformation rate decreased to achieve the low resolution in high speed mode.
6 At an appropriate point in the rotation of the drum, e.g. approximately 64 degrees from the TOP or zero reference, as determined by the 2- pulse outputs from detector 39, the laser beam writes data on the drum. In this system it is written such that the beam is on where white is to appear in the final copy, i.e. the beam is discharging the photoconductor to wipe out all the unnecessary information. While this is happening the paper in either an upper paper tray 41 or a lower tray 43 is caused to enter the machine. This is achieved by energizing either escapement 45 or 47 which take the paper 1~ from the appropriate tray and put it into the feed track.
Typically, different size paper is used in the trays and ~he tray which is to be used is selected by the operator.
The paper moves along th;s track under the influence of rollers 44 driven by a chain attached to motor 40 until it comes to a gate 46. The gate holds the paper there and does ~ome alignment of the paper to eliminate skew because the gate is a flat parallel plate and the driving rollers are moving ~o as to keep the paper pushed against the gate. At the correct angle (time) for assuring a transfer of the toned image on the 2~ photoconductor drum to the paper, e.g. at about 136- of rotation, a solenoid attached to gate 46 moves the gate and allows the paper to continue moving. The paper and the toned image on the drum thus come together at the correct location. At that point, the charge on the drum takes over and pulls the paper to it so that the drum now controls movement of the paper.

1 The next significant point occurs when the paper passes under transfer corona 42 whi~h a~ts to transfer the toned image to p~per. This transfer corona is turned on ~t the appropriate point $n the cycle to ~ssure t~tal transfer of the ~age. Under this corona the toner is transferred to the paper ~nd the paper keeps on m~v~ng.
As the photoconductor drum rotates and the paper passes the transfer corona, the paper must be removed from the drum. In this particular ~yste~, there is a piece of tape at ~ne edge of the drum such that the edge of the paper never directly contacts the ~rum. The tape leads that edge of the paper into rollers 49 located just beyond the transfer corona. When the paper comes to the other 6ide of the transfer corona, the charges holding the paper to the drum have been fairly well eliminated ~o the rest of the paper can be easily peeled from the drum.
Beyond rollers 49 the paper i~ p~cked up by the rollers of foser 48. These rollers extend acro s the entire width of the p~per ~nd pull it away from the drum. Also these rollers use heat and pressure to cause the toner to deform, melt and adhere to the paper. Then the paper with the image on it comes out of the system.
The machine can run at various speed and resolution combinations. Consequently, the fuser heater 31 must be able to vary the temperature to the fuser under program control so that fusing can occur properly at different speeds. The fuser iB made up of silicone, urethane or Seflon coated rollers which are ~aintained under ~ certain level of spring pressure to squeeze the toner into the paper ~8 it is being heated.
wick 55 containing silicone oil is u~ed for wiping ~ the lower roller with oil. Between printing stages some of * - Tra~e klark.

1 the silicone oil on the bottom roller transfers to the upper roller. This oiling of the fuser rollers is done to keep them smooth and clean 50 no toner is transferred tu them from the paper. A transfer of toner to these rollers could cause jams, adherences and so on~ There is also a scraper in the fuser that ~crapes off any toner that may stick to the upper roller despite ~he oil.
Prior to the rollers 49 there is pos itioned a separa-tion sensor 51. The sensor 51 detects when the paper properlylO separates from the drumO There are also paper jam de~ectors 53 located along the paper path before the drum. The signals from these sensors are used by the microprocessor in a conven-tional fashion to assure that the system is operating properly.
If these sensors detect a paper jam the system will go into an immediate shut down. For other less critical system faults the system will go into a delayed or orderly shut down.
As the drum comes around after the paper has been peeled off, there may still be residual toner on it. To eliminate this toner for the next image, a scraper blade 33 is 2n used. This blade, which preferably is made of urethane, but could be made of other materials, scrapes the toner off the surface of the Mylar dielectric and drops it into a well 33'.
There is an auger in the well which keeps driving the waste toner forward so that it falls out of a hole in the well into a waste toner bottle. Attached to the bottle is a replenishment sensor 33'' which indicates whether the waste toner bottle has been replaced. There is a control in the machine that requires that after a certain number of copies the waste toner bottle be replaced. The machine counts the number of copies and requires replacement of ~he bottle when the number is exceeded.

1 The sensor determines if the bottle has been replaced with a new bottle when this count i~ exceeded~ If the bottle is not replaced, the machine goes into a delayed shut down and ~tays that way until the bottle ic replaced.
6 After the 6~raper blade 33, the drum come~ under ~ DC corona 34 which ~ends to neutralize any surface charge t~t is left. Some of this charge may be due to some electro-6tatic interaction between the blade and the dielectric.
Referring to Fig. 2, there is shown the data handler l~ ~ircuit 70 and the 6ystem clocks and timing. The main clock is generated by a crystal 71 and its output goes through clock timing generator 71 to timer/divider circuit 73 where it is divided down in ~any ways. These divided clock 6ignals are used to control the system motors, i.e. the motors for the 16 paper path, drum and polygon.
The scan modulstor 75 is used to clock the pel data because the optical system does not move the beam at a uniform velocity across the drum. In effect the scan modulator compen-sates for this by creating a clock ~ignal for reading out the pel data which is offset in time according to data stored in the PROM 210.
To obtain this pel clock signal a divided clock signal from circuit 71 is compared in a phase comparator 220 with the output of a VCO 216 after it has been divided in divider circuit 218. The error ~ignal from this comparison ~s then fed through summing circuit 214 to the VCO so it will be locked to the divided crystal frequeny. However, to vary this frequency in a cosinusoidal manner to compensate for scan speed error, a correction signal from digital-to-analog converter 212 is summed in circuit 214 with the phase error signal. The l input needed for the correction is ~tored in PROM 210 whose contents are addressed by address controller 211. In turn, address controller 211 is driven by the ~ystem clock 80 that for each clock pulse there is a new correction ~ignal and a 6 continuous frequency modulation of the clock rate occurs across e~h scan. In order to reset thi6 circuit and other~ at the begin~ing of each ~can line, the SOL ~ignal is applied to clock circuit 71 and the pel clock ~ignal is taken from that circuit.
The pel clock is applied to address read/write control 230. This circuit which is actually controlled by the microprocessor, reads data into shift register 232 from the appropriate memory A or B at the varying pel clock rate. In the meantime, control circuit 230 is causing RIP data from interface 60 to be fed through OR-gate 236 to the other memoryr Instead of actual data, test data from test pattern generator 240 can be passed through gate 236 to one of memories 72, 74.
The test signals from test pattern generator 240 are created from a timing 6ignal produced in c~ock generator 71.
Memory data, whether it be the test pattern informa-tion or actual raster data, is read out of the appropriate memory through OR-gate 76 to shift register 232 of output logic 78. The data can then be ~hifted from this circuit at the pel clock rate or at a division of the 6ystem clock rate. From the shift register the data is applied to output logic circuit 234 that prepares it for the laser driver. This may be done by inverting the data bits of the system to write the image areas, i.e. write black rather than erase the background areas, i.e.
write white. Al~o, the signal may be changed from return-to-zero format to non return-to-zero as needed for the laser driver.

~Z54~

l As ~hown in Fig. 2, the microprocessor 80 that controls the printer has an address bus and a data bus. Over these lines an input/output decoder 242 is instucted to generate enable pulses e that ~ynchronize the operations of various 6 parts of the sy6tem, e.g. gate 236~ generator 71 and stepper notor addre~s control circuit~ 434, 444. In addition, the lnterf~ce 60 is informed by the microprocessor 80 ~hen the ~ystem is ready to receive data and receive6 other instructions over a command buffer 246. The buffer 246 al50 receives information on line sync and end-of-page via write control circuit 244 and supplies it to the microprocessor. Information on the resolution-speed mode selected by the user is transmitted to the rest of the system from the microprocessor via print control circuit 248. For example, the output of circuit 248 is l~ delivered to the fuser heater control to ~et its level. The user also sends information to the microprocessor on the size of the paper, resolution, paper tray and other user selected information through command buffer 246.
The laser driver circuit shown in Fig. 3 modulates the current to the laser 10 and effectively turns the laser on and off. Current from a constant current source 319 determines the maximum current permitted to go through the laser. The laser is a laser diode with a built in photodiode that monitors the laser light output and provides feedback. Thus, there is a 26 feedback circuit 312 that maintains constant light output.
To prevent the diode from blowing out, the driver circuit makes sure that the current is limited within a certain specified range. In addition, there is a calibration circuit 320 which keeps the laser on continuously prior to start-of-line.
~herefore, at the appropriate time in the polygon synchronization 1 cycle, the data drive oper~tion i8 aborted and the laser is turned on fully with no modulation occurring on the diode.
This selection i~ made under program control by applying the CAL signal to circuits 3t8 and 320.
6 The pel data i~ applied to the data current ~odulator circuit 3~6 along with interlock and pel gate signal~. The data current modulator 316 delivers a ~ignal to a ~tchdog tlmer 318. The watchdog t$mer ~akes sure that the laser driver i8 running properly. Since it i~ harmful for the laser to stay on continuously or at too high a current for too long, the watchdog ti~er monitors the data current modulator 316 and automatically shut~ off the ~urrent generator 310, and therefor the diode, if safe operating condition~ are exceeded.
As previously noted, the printer can cperate in either 16 a hlgh or low resolution mode and this i8 under program control.
One output of the program ~8 a H/L Res, i.e. high-low resolution signal, which i6 supplied both to the mode circuit 314 and the ~urrent modulator 316. The current level or the power output of the laser diode thus i~ changed as a function of whether the system is running at low resolution i.e. under 400 dot~/inch, or high resolution, i.e more than 500 dots/inch. Less laser power is needed at high resolution since more dots are packed into the same area. The mode circuit 314 al60 has a ~cal~ or calibration input to bring the diode up to the right level 26 based on the ~eedback from the photodiode.
Fig. 5 shows the general arrangement o~ the ~ystem control, which i8 basically a Motorola 68000 microprocessor 500 programmed to operate as a state machine according to instruc-tions ~upplied by the manufacturer. The microprocecsor controls the whole operation of the system. It has a clock inp~t which * - Trade Mark ~s~

1 comes from crystal 71'. The processor also has RAMS and PROMS
as memory units. Further, it includes a UA~T, i.e. a universal asynchronou~ receiver transmitter device used for putting serial data in an RS232 format. These uni~s are connected together by an address bus, a data bus and a control bus.
In operation the processor 500 utilizes interrupt control 502, i.e. there are numerous ~ignals directed to the processor which interrupt it to tell ~he processor that the system is at a particular point and requires instructions.
One such ~ignal is the 2- signal from the drum encoder. Every 2- it requires that the processor check to see ~hether there is something to do. Another signal is the ~top of the page~ or TOP signal which i5 the zero reference on the encoder 39' attached to the drum. There are a whole series of such signals that indicate that the fuser is ready, the toner is low, the toner bottle is to be replaced, etc. There are also interlocks such as door switohes, scrapers blade position, tray in place, etc. Further, there are jam detectors 53 that tell if the paper is at a certain point at a certain time, and a separation ~ensor 51 that tells if the paper has separated from the drum.
The various signals come from different parts of the machine and interrupt the processor to ask for further instructions or to indicate status. These ~ignal6 reach the processor through input buffers 510 and I/O port 515. The interrupts go directly 26 to circuit 502, but the other data received is applied to the processor through data bus buffer 520.
The microprocessor, by knowing where the system is at a particular time, knows when to do certain things. This information i6 dellvered over data bus buffer 520 and address bus buffer 522 to the ~/O port 515 and from there to the system ~zs~

l through output buffers 512. For instance, the processor, over the appropriate output port and at the ap~ropriate time, will turn on the post exposure lamp by applying a signal over buffer 512 to turn on the power supply for that lamp.
The laser printer also has a display 530 to aid operator use.. -The data bus comes out to a 16-character liquid crystal display 532 and some LED's 534 which are the operator interface. As a result, the ~tatus of the 6ystem, e.g. system ready, paper jam, e~c. can be displayed for the operator.
In Figs. 6A and 6B, there is shown a flow chart of the executive routine for the microprocessor which controls the operation of the laser printer. This routine is interrupt driven so as to cause it to branch to certain simple subroutines that handle individual system operations.
16 At the beginninq of the program, the entire system is initialized in the EXEC ~tate 600. When this is complete, the program moves on to XEC LOOP 602. In this loop, the program first checks to see if there is a 2- in~errupt. If not, the program moves immediately to state 604 where it checks for an immediate shut down condition due to a paper jam. If in state 602 a 2- interrupt is found, the program checks for critical action points.
Critical action points are degree~ of rotation of the drum where action must be taken to continue the operation. A
26 table is prepared which corresponds degrees of rotation of the drum with various states of the machine and provides particular action that must be taken. Thus, the system has a great deal of flexibility in that by changing the critical action points or the microprocesor's response to those action points, the operation of the machine can be varied. A typical critical 1 action point is the 64- point in the rotation ~f the drum when printing ~ith the laser is to occur, provided the system is in a normal ready condition.
After the critical action point is checked and any 6 required ~ction i8 taken, the 6y~tem then checks for possible jams by checking paper jam 6ensorR 53 a~ it normally does when there is no 2- interrupt. Following this, the check for immediate shut down in state 604 ifi made.
If a flag is set indicating that immediate ~hut down should take place, the program branches ~o state 605 which executes the immediate shut down procedure. If no immediate ~hut down i6 found, the program proceeds to test for manual feed roller use in state 606. This part of the program allows a user to input paper of a size different than that included in the paper trays. Thus, ~t requires activation of the feed rollers without activation of the escapements 44, 45.
After the manual feed roller check, the program checks to see if there is a fault ~n the toner supply. If there is, the program moves from state 608 into state 610 which sets a flag. This allows the system to continue to produce a limited number of additional copies, even though there is an indication that the system is out of toner. If no toner fault is detected, the ~ystem skip6 over section 610 to state 612 of the program which checks the rest of the faults.
Once a flag has been set in state 610, and after the preset number of copies have been made, the program branches to 6tate 611 which executes a delayed shut down. This differs from immediate shut down in that there is no need to rapidly remove power from parts of the system in this state. If the flag is not 6et, the program drops into state 612 where the other faults are checked.

~2S~

1 If one of the faults checked in state 612 indicates th~n an immediate shut down is required for other than a paper jam which was checked in Etate 604, the program will branch to state 605 and execute the immediate shu~ down. Such a fault 6 ~ight include an overheated motor. In state 612, delayed shut down situations, ~uch a~ loss of laser power, are chec~ed and if one of them occurs the program branches to state C1t to execute the delayed ~hut down.
If no faults are detected, the program branches to ~tate 616. If there is a fault in ~tate 612f but it is not an immediate shut down or delayed shut down fault, the program enters state 614 where a check is made to see if paper is available. The program will continue to loop between states 614 and 612 until paper is provided. Then the program will 16 pass on to state 616.
In state 616, the program checks to see if a command error fault has occurred or if there is no valid command pending. It also checks the state'of the machine. If no command is available, the program branches to execute a delayed shut down in state 611. If a command is available, the program moves to state 618 to see if the command is valid.
In state 619, a check is made to ~ee if the ~ystem is in the test mode and then the program passes to state 620 where a test is made to see if the printer is in machine state 6.
2~ Machine state 6 is the stopped and ready for command mode. In this position, the program inquires whether there are any manual feed commands or test mode commands. If there are no pending commands and no manual feed, the program branches to state 624. If there is manual feed command, the system branches to state 626. Otherwise, the program falls through to state lz5~

622 where a check is made for a pending command. If such a pending command i6 available, the program loops back to test for manual feed roller use in ~tate 606. Otherwise, it passes through ~tate 624 where the system checks to determine if it is 6 6till in the test mode.
After the ~heck in state 624, the program pa~ses to ctate 626 where the front panel display routine i6 executed to deliver information to the user and the manual feed roller is checked again. Finally, a check is made to ~ee if there is a requirement for an immediate shut down. If there is no immediate shut down condition, the program branches to state 630. If there is a requirement for immediate hut down, a check is made to determine if this is due to a paper jam whether the paper jam has been cleared and whether the paper 16 jam reset button has been pushed. If the reset button has been pushed, the program branches from state 628 back to state 600. If the button has not been pushed, the program falls into ~tate 630 where the loop chec~ is carried out.
In loop check, housekeeping duties are taken care of, including updating the display and sending signals to the watchdog timer of the laser timer to keep it from shutting down the system.
The operation of the executive routine ~hown in the flow charts of Figs. 6A and 6B, in combination with a critical point table, cause operation in the manner desired by the user. The details of programs for carrying out this flow chart will depend on the particular program, microproces60r or logic system used.
At the command of the operator and under the control of the microprocessor, the xystem can be switched from the ~2~;2~

high resolution, moderate speed mode (resolution in excess of 500 dots/inch and a speed of about 4 pages/minute) to the lower resolution, high ~peed mode (a resolution under 400 dots/inch and a speed of about 16 pages/minutés). The program 6 of the microproce6sor accomplishes this rapidly by sending higher clock rate pulses to the stepper motors ~o that the paper and photoconductor drum move more quickly. This reduces the vertical resolution by crea~ing a wider 6pacing ~2tween the raster ~can lines.

With the paper and the photoconductor drum moving faster, the microprocessor causes an increase in ~he output of the laser, the fuser heater temperature and the corona currents. As a result, the ~ame image definition or contrast will be produced in the low resolution mode as in the high 16 resolution mode.
No change is made to the optics ~o that the spot size, which produces the dot pattern that results in the image, remains ~he same. The resolu~ion ~ifference occurs because the spacing between the dots in both the horizontal and vertical direction is increased.
In order to increase the dot spacing in the horizontal or 6weep direction without changing the polygon speed, printing occurs using every facet of the polygon. In the high resolution mode, printing occurred with every other facet, but this high 2~ resolution printing included in one scan line all of the data that had been 6tored during two scan periods. Therefore, twice ~s much data was applied in a single scan line in the high resolution mode. In the low resolution mode only the data taken in during once scan period is laid down on the photoconductor.
Thus there is a much greater spacing between the information dots or picture elements.

~2S~2~

This 6cheme for utilizin~ fewer facets during the high resolution phase, but printing twice as much data during each ~can, also allows the interface circuit to remain constant.
Therefore, fewer changes in the ~ystem are necessary in order to arrive at the dual mode laser printer of the present invention.
While the present invention ha6 been particularly shown and described with reference to a preferred embodiment thereof, it will be understood by those ~killed in the art that various changes in form and details may be made therein without departing from the ~pirit and scope of the invention.

lB

2~

Claims (5)

What is claimed is:

1. A laser printer system having at least two operating modes, said modes differing from each other in terms of resolution and speed such that the higher the resolution the lower the speed, comprising:
a photosensitive medium;
means for generating a modulated beam of laser light focused onto said medium;
at least one moving mirror surface located in the path of said focused light beam before said medium for reflecting the beam such that it sweeps across the medium;
detector means for detecting the start of sweep of the beam across the medium and producing a start of line signal;
clock means for producing a plurality of related clock signals;
photosensitive medium motor means for moving said photosensitive medium at a rate determined by a first one of said plurality of clock signals; and control means for controlling the modulation of said laser beam according to a second one of said plurality of clock signals and the start of line signal, said control means causing the printer to operate in at least (1) a high resolution mode wherein the light beam is modulated at a high rate determined by the second clock signal during fewer than every scan by the moving mirror surface and the first clock signal causes the medium to move at a slow speed, and (2) a low resolution mode wherein the light beam is modulated at a lower rate by the second clock signal during a greater number of scans by the moving mirror surface than the higher resolution mode and the first clock signal causes the medium to move at a faster speed.

2. A laser printer as claimed in claim 1 wherein the medium is a photoconductor drum of an electrophotographic process that includes a corona charge generator for developing corona charge, a developer for developing an electrophographic image on the photoconductor drum, paper motor means for moving paper through the system, a transfer means for transferring the developed image to the paper and a heat fuser for applying temperature to the developed image on the paper to fuse it to the paper.

3. A laser printer as claimed in claim 2 wherein said control means causes the corona charge, paper motion and fuser temperature to be reduced in the high resolution mode from that in the low resolution mode.

4. A laser printer as claimed in claim 3 wherein the photoconductor medium motor means and the paper motor means are both precision stepper motors driven by one of the plurality of related clock signals.

5. A laser printer as claimed in claim 1 wherein the moving mirror surface is formed as a facet of a multi-faceted rotating polygon.