DE4432078A1 - Vehicle mounted combination audio-video system - Google Patents

Abstract

The system includes multiple audio-video components connected together in a data network for transmitting audio, video and control data. Each component is controlled separately in the form of switching logic responding to any signal applied to a component through one of the data lines. The data lines can be optical conductors or optical fibres and the switching logic is equipped with a light detector converting the signals for the audio and video components.

Description

The invention relates to an audio or / and video system with a plurality of audio / video components that use data line connections for the transmission of audio / Video and control data are combined in a local network, and with means for switching on individual components.

Such systems are primarily installed as sound systems in vehicles, whereby the system components tuner, Ver stronger speaker combinations, a CD changer, a control console u. the like include. The components are preferred, optionally using Optical fibers as data line connections, put together in a ring structure closed. To power all components is one with the vehicle battery connectable ring line provided. Other electrical line connections serve to turn on individual components, such line ver Connections through a ring bus line via which the individual components are connected speaking address signals are transferable, or by individual, to the components leading switching lines can be formed.

The laying of electrical lines in addition to the main supply line and the data line connections make the installation of such systems difficult. Self then when the ring bus line together with the data connection lines would be laid within a bundle cable or the like comprising all of these lines, the installation would require a lot of effort because the data lines and the cables for switching on connected to the respective components  must be and also locally in different places, so that they before Connections are to be separated from each other.

It is the object of the present invention to provide an audio or / and video system to create the type mentioned, its installation over known the like systems is simplified.

The system according to the invention which achieves this object is characterized in that that the components as switching means have switching logic that are based on any responds via one of the data line connections present signal.

According to this solution of the invention, the individual switching on requires individual comms components no additional to the main supply line and the data lines Lines, which significantly reduces the installation effort.

In a preferred embodiment, the switching logic comprises an on / off switching logic to switch off the component if there is no signal. Be advantageous there due to data not supplied during system operation and therefore in operation Components not included, relieving the supply voltage source shut down.

Preferably, the shutdown is delayed after the absence of a signal, so that short interruptions in signal transmission, which are common during operation, do not occur an unwanted, possibly the short-term resuming signal transmission disruptive shutdown.

In a preferred embodiment, optical fibers are used as data line connections provided, and the switching logic contains an incoming light detecting detector gate, whose output signal can be used as a switching signal. For delayed off switching a component can cause the output signal of the light detector to fail from light and according to a circuit having an RC combination sound.

The light detector can advantageously be used not only as a component of the switch-on logic also used as a signal converter for data signal conversion during operation will.  

Further advantageous design options of the invention are given in the Sub-claims emerge.

The invention will now be based on an embodiment and on this off management example related accompanying drawings explained and be be written. Show it:

Fig. 1 shows an embodiment of an inventive audio / video system arranged in a ring structure audio / video components (schematically)

Fig. 2 is a schematic representation of a ver in the embodiment of FIG. 1 used audio / video component,

Fig. 3 is a schematic representation of an adapter used in the audio / video component of Fig. 2 for the reception and transmission of data, and

FIG. 4 shows a basic circuit of an on / off switching logic contained in the adapter according to FIG. 3.

With the reference numeral 1 in Fig. 1 denotes a ring line, which with a voltage source of a voltage of +12 V, z. B. a car battery, can be connected via a switch. Audio / video components 2 to 8 are connected to the ring line 1 . Contrary to the exemplary embodiment shown, components could be provided in larger or smaller numbers. The components can e.g. B. include a tuner, a control panel, a CD changer, several amplifier-speaker combinations, a television, a telephone and / or the like. The audio / video components 2 to 8 , each provided with a ground connection, are each connected to one another via a data line, the data lines being designated 9 to 15 . In the exemplary embodiment shown, the data lines 9 to 15 are each formed by an optical fiber via which audio / video and control data can be transmitted in series.

Fig. 2 shows the basic structure of the audio / video components 2 to 8. A bounded by the dashed line 16 ge, connected to a + 12V ring supply line audio / video component contains an adapter 17 with an input for an optical fiber 18 and an output for an optical fiber 19th The fiber optic be designated 18 and 19 each correspond to one of the data connection lines 9 to 15 in Fig. 1. The adapter 17 is connected via a switching line 20 with an audio device part 21 of the component shown. There are also data bus connections 22 and 23 between the adapter 17 and the audio device part 21 for the transmission of audio data or control data.

As can be seen from FIG. 3, the adapter 17 contains a light receiver 24 connected to the optical waveguide 18 and a light transmitter 25 connected to the optical waveguide 19 . The light receiver 24 is connected to a transceiver 27 via an output and the light transmitter 25 via an input. The connected to the transceiver 27 output of the light receiver 24 is also in conjunction with a switch-on logic 26 , which is constantly connected to a + 12V voltage source. The transceiver 27 is connected to a microcontroller 30 via a system bus line 29 . Further bus connections 31 and 32 for audio data are established between the transceiver 27 and the audio device part 21 . The microcontroller 30 is connected to the audio device part 21 via a control data bus 33 .

As will be explained in more detail later, a switching line 28 connected to the transceiver 27 and the micro controller 30 can be connected via the switch-on logic 26 to a + 5V voltage supply unit, not shown in FIG. 3.

The switch-on logic 26 is shown in detail in FIG. 4. The light receiver 24 connected to the optical waveguide 18 can be connected via a line 42 and a switch 41 via a resistor 38 to a 12V voltage source. An output line 43 of the light receiver 24 is connected via a resistor 44 to the base of a switching transistor 35 , the collector of which is connected via a resistor 45 to the base of a further switching transistor 36 . A capacitor 34 is provided between line 42 and line 43 . The + 12V voltage source is connected via a switch 40 to a voltage regulator 39 providing a constant voltage of + 5V. The two switches 40 and 41 are components of a relay 37 , which is provided in a line connection between the + 12V voltage source and the collector of the switching transistor 36 .

Before the special function of the switch-on logic according to FIG. 4 is discussed, the mode of operation of the audio system shown in FIGS. 1 to 3 will first be explained.

In operation of the system, the individual components 2 to 8 can both receive and process data via the data connection lines 9 to 15 , and also generate and send data or only forward received data. This data traffic can be program-controlled on the one hand, but also controlled by hardware components on the other. An audio component that works, for example, as a tuner constantly sends audio data that are received and processed by amplifier-speaker combinations around comprehensive components. In the ring structure, for example, components provided between the tuner component and the amplifier / loudspeaker combinations would possibly only pass on this data. If a component is to receive and process data and / or is to generate and send data, relevant signals transmitted via the data line connection, in particular control signals, can be accompanied by corresponding address signals to which those components respond for which the respective signals are intended. The addresses can be z. B. be permanently assigned or change programmatically during the operation of the system.

One of the components, e.g. B. a console could perform a master role and provide the system clock that is binding for all components.

The signals transmitted through the optical fibers 9 to 15 are each received as serial data by the adapter 17 and converted into audio and control data that can be processed for the audio device part. Furthermore, data that is not specific to the respective audio component is simply forwarded by the adapter. The transceiver 27 contained in the adapter 17 takes on these tasks. The microcontroller also contained in the adapter takes over control functions between the transceiver and the audio device part, such as. B. the implementation of commands and status data that come from the audio device part and are to be forwarded to another audio component. Furthermore, the microcontroller implements commands that come from other components, so that the incoming commands can be directed both to the audio device part and to the transceiver.

The mode of operation of the switch-on logic shown in FIG. 4 will now be explained. When a component is not switched on, the switch 41 connects the light receiver 24 via the line 42 and the resistor 38 to the + 12V voltage source. The resistor 38 ensures such a voltage drop that between 5 and 6 volts are present as the operating voltage for the light receiver at the input of the light receiver 24 formed, for example, by a photodiode. If no light signal is present, this voltage value also occurs on the output line 43 of the light receiver 24 . When light signals arrive via line 18, the light receiver 24 generates an increased voltage on line 43 , by means of which the switching transistor 35 is brought into a conductive state and a connection between the 5 to 6 volt line 42 and the base of the further switching oil Sistor 36 is made. As a result of the voltage at the base of the switching transistor 36 , the transistor 36 becomes conductive and a current flows through the relay 37 , as a result of which the switch 40 closes. Furthermore, the switch 41 closes and binds the line 42 to the output of the + 5V voltage regulator 39 . By closing the switch 40 , the voltage regulator works and supplies +5 volts at its output. In addition to the light detector 24 now operating as a converter for incoming data, all parts of the video component, e.g. B. also the transceiver and the microcontroller, connected to the +5 volt supplying voltage regulator 39 and the component is switched on. If the light receiver 24 does not receive any light via the optical waveguide 18 , the voltage on the output line 43 does not immediately drop to the value between 5 and 6 volts, but decreases in accordance with the time constant, which is determined by the capacitance of the capacitor 34 and in the output line 43 contains resistances. The transistors 35 and 36 are thus switched with a time delay and the relay 37 switches over with a corresponding time delay when the switches 40 and 41 are actuated. The time constant is expediently dimensioned such that the interruptions in the data flow on line 18 which are usual during operation do not yet result in a shutdown of the component.

In the exemplary embodiment shown here, the individual components 2 to 8 of the audio system can each be switched on one after the other. The prerequisite for this is that one of the units, for example the console, generates a light signal, which is triggered by an initial switch-on process, without the application of light via its input connecting line and which is sent to the next audio component. When signals from this audio component are present, it is switched on in the manner explained. When the transceiver is switched on as a result, this component is then able to transmit light signals and bring the next audio component into the switched-on state. Continuously, the entire ring shown in FIG. 1 can be put into operation in this way.

The light signals causing the switch-on can be data signals, but also from them different switching signals in the format. Are the data signals as  Generated modulations of a basic signal, the basic signal itself can also be used as Switching signal can be used.

Signals no longer arrive at one of the audio components, for example because If this component is not required during operation, it switches component auto matically and no longer stresses the voltage source, for example the car battery.

In the exemplary embodiment shown, a comm is in the switched-off state component only the power on logic. The shutdown could e.g. B. But only to the extent that, in addition to the switch-on logic, the transceiver remains supplied at least to the extent that data forwarding is guaranteed.

Claims (10)

1. Audio or / video system with a plurality of audio / video components ( 2 to 8 ), which are connected via data line connections ( 9 to 15 ) for the transmission of audio / video and control data in a local area network, and with means for respective switching on of individual components, characterized in that the components as switching means have a switching logic which responds to any signal applied to the component via one of the data line connections. 2. System according to claim 1, characterized, that the switching logic is an on / off switching logic for switching off the component in the absence of such a signal. 3. System according to claim 2, characterized, that the on / off switching logic for time-delayed switching off after the Signal is provided. 4. System according to one of claims 1 to 3, characterized, that the component based on a standby state in which at least the switching logic is connected to an operating voltage source is switchable. 5. System according to one of claims 1 to 4, characterized in that optical fibers ( 9 to 15 ) are provided as data line connections and the switching logic has an incoming light-detecting detector ( 24 ) with an output signal that can be used as a switching signal. 6. System according to claim 5, characterized,  that the output signal for switching off the component with a delay Absence of light according to an RC combination Circuit subsides. 7. System according to claim 5 or 6, characterized in that the light detector ( 24 ) can be used as a signal converter for incoming audio / video and control data. 8. System according to one of claims 1 to 7, characterized in that the components ( 2 to 8 ) have a data input and a data output and the components for processing or / and forwarding received data and for generating and sending data in a unidirectional data traffic are provided. 9. System according to one of claims 1 to 8, characterized, that the components are combined in a ring structure. 10. System according to claim 8 or 9, characterized, that the processing and generation of data by individual components over Address signal data is controllable and not addressed by an address signal Components only forward incoming data.