DE19709313A1 - Integrated circuit for optical disc player - Google Patents

Abstract

The integrated circuit (1) has a single-chip configuration and includes an A/D converter (6), a digital signal processor (8) and a decoder (7), together with a switching device allowing intermediate focussing error or tracking error signals to be obtained from the audio data output channel. The switching device may be incorporated in the digital signal processor, with the switching effected in dependence on the selection of corresponding IC parameters, or alternatively the switching device is programme-controlled.

Description

The invention relates to an integrated circuit for use in an optical record player such as CD Players, optical magnetic disk players, CD-ROMs, digital Video discs, etc., the playback or Recording device for optical recording media completely or partially a so-called "ON-CHIP" - Configuration and the chip has a digital Signal processor, a decoder and one Microprocessor unit includes.

For cost reasons, it is the aim to opt for Turntables, such as compact disk players, if possible all necessary for the operation of the player Functions in an integrated circuit too concentrate what is under the catchphrase "EIN-CHIP" - Configuration is known. In such a case included the integrated circuit (IC) both the decoder and also the servo functions. Thereby, the operation of the optical turntable from the signals of the optical Optical turntable scanner various Error signals derived, such as that Focus error signal and the tracking error signal, which in the digital servo calculation of the ICs used to Control signals for the actuators of the optical To generate the scanning unit. In these calculations the Control functions derived from the various Error signals continue to occur so-called intermediate signals on. To get these signals, i. H. Error signals and To be able to observe intermediate signals, for example in order to To control their accuracy are currently additional pins on the integrated circuit arranged these generally as intermediate signals  route the designated signals to the outside. Providing Such additional pins inevitably increase costs and the complexity of the integrated circuit. Farther can lead out the intermediate signals under certain circumstances a different division of the integrated Circuit configuration does what the cost elevated. Furthermore, to determine the tracking error or Focus error signal still additional circuits between the optical scanning unit and the digital servo and integrated decoder circuit to the Increase observability. But that is the principle the "ON-CHIP" configuration deviated and the whole Circuit is due to the additional components more expensive.

The invention is therefore based on the object to create integrated circuit in which the Possibility of observing the intermediate signals without either using additional components or additional pins are provided on the integrated circuit will.

The task is determined by the characteristics of the item solved according to claim 1. Advantageous embodiments of the Invention are the subject of the dependent claims.

The present invention relates to an integrated Circuit for a CD player with a so-called "ON-CHIP" configuration, with the integrated circuit an A / D converter, a digital signal processor and includes a decoder. The inventive one integrated circuit a switch to which Intermediate signals, such as the focus error or the tracking error signal, on the audio data output channel can be placed. The switch is advantageous of the integrated circuit according to the invention in digital signal processor arranged, the switching  by choosing appropriate IC parameters can be. Furthermore, the switch is program controlled, and the program control of the The switch is in the memory of the integrated circuit or its digital signal processor.

Furthermore, the integrated circuit according to the present invention a digital / analog converter for Convert the audio signals and an output unit to Output digital audio signals on.

The integrated circuit also has a Microprocessor unit to control the overall process.

The inventive implementation of the integrated Circuitry therefore has the following advantages:

The integrated circuit has fewer pins, but a greater direct observability of Intermediate sizes or intermediate signals, including the Focus error signal and the tracking error signal is given.

Due to the software solution for the digital Servo part becomes more flexible for observation or output of the intermediate signals and error signals achieved.

Furthermore, a cost saving is due to the given fewer ports and there will be none additional hardware for the necessary modifications needed.

A preferred embodiment of the invention is described below with reference to the drawings, in which:

Fig. 1 is a block diagram of a CD-player system in the "ON-CHIP" shows configuration,

FIG. 2 is the standard audio I / F output format for compact disc shows

Fig. 3 shows the output format of the focus error and the tracking error signal in the audio I / F channel, and

Fig. 4 shows the digital signal processor part of the integrated circuit according to the invention in greater detail.

Fig. 1 shows a block diagram of a CD player in which the "ON-CHIP" technique is implemented. A compact disk 2 is arranged in the CD player 1 and is read by an optical scanning unit 3 . Such optical scanning units 3 are known and are therefore not described further. A plurality of photodiodes or photosensitive surfaces are arranged in this optical scanning unit 3 , so that six photodiode signals A, B, C, D, E and F are obtained in this embodiment. Because of the arrangement of the photodiodes or photodiode fields, in addition to the desired audio signal and / or video signal, focus errors and tracking errors, for example, can be derived from the combinations of the photo signals in a known manner. The photodiode signals A, B, C, D, E and F are fed into the integrated circuit 5 via an input 4 . The photodiode signals A, B, C, D, E arrive there in an A / D converter 6 , which splits the signals into an HF part for the audio signals and into certain intermediate signals for determining, for example, the tracking error signal or the focus error signal, namely in the present embodiment in the intermediate signals A + C, B + D, E and F. Furthermore, the integrated circuit 5 comprises a decoder 7 and a digital signal processor 8 . The decoder 7 processes the audio signals, carries out error correction of the audio signals according to a known method and outputs the audio signal output. The digital signal processor 8 determines the digital servo signals from the diode signals A, B, C, D, E, F, G and carries out the audio oversampling and de-emphasis filtering. From the digital signal processor 8 , an actuating signal is output on the outside to corresponding actuators (not shown) of the optical scanning unit 3 , which makes the corresponding corrections on the optical servo, for example changing the focus or tracking the track just scanned, etc. For audio oversampling and the deemphasis filtering, the audio signal from the decoder 7 is given to the digital signal processor 8 , processed there and transmitted back to the decoder 7 . The decoder 7 has outputs SDA48, SDK48 and LRCK to the outside, which in the first embodiment shown are applied to an audio-digital / analog converter 11 . The meaning of the three output lines will become apparent in FIGS. 2 and 3. Furthermore, the integrated circuit 5 also has a unit 9 for outputting digital audio signals which are taken from the decoder 7 . For overall control of the integrated circuit 5 , the latter also has a microprocessor unit 10 . The output signals SDA48, SDK48 and LRCK arrive in an audio-digital / analog converter 11 , which has a corresponding left and right audio channel CH1, CH2 as an output. The output channels CH1, CH2 of the audio D / A converter 11 are connected to an amplifier and loudspeaker unit 12 or an oscillograph 13 . By setting appropriate program parameters in the integrated circuit 5, it can be caused that instead of the audio signals via the channels SDA48, SDK48 and LRCK, the focus error signal or the tracking error signal are output by the digital signal processor 8 instead of the audio signals, these actuating signals or other intermediate signals to the decoder 7 submitted for output. In this case, the analog track error or focus error signal is present on the left and right channel CH1, CH2 behind the audio D / A converter 11 , which is then measured or measured using the oscillograph 13 .

can be made representable. In this case, of course, no audio signals can be emitted via the amplifier / loudspeaker unit 12 . If music is to be heard at the same time during the measurement of the focus error signal or tracking error signal, then in this case the digital output D _{OUT of} the digital output unit 9 of the integrated circuit 5 can be used, which feeds the digital audio signal to the amplifier / speaker unit 12 . However, the amplifier / loudspeaker unit 12 must then have a corresponding D / A converter (not shown).

FIG. 2 shows the output channels LRCK, SDK48 and SDA48 addressed in FIG. 1 when the channels are occupied with the standard audio output format I / F for a compact disk. One information unit is 22 μs corresponding to the inverse value of a frequency of 44.1 KHz. The LRCK channel is the clock signal for distinguishing between the left and right channels. Ie, in the present case, logic 1 means left channel, while the right channel is formed by logic 0 of the LRCK clock signal. The SDK48 channel contains the clock for serial data transmission. According to the diagram or the standard output format, an information unit comprises 48 SDK clocks, ie 24 bits per channel. The audio information is encoded in the channel SDA48, 16-bit audio data being available for each channel, that is to say 32-bit audio data for both channels. For the left audio channel, these are bits L0 to L14 and MSB L15. Similarly, the right audio channel includes audio bits R0 to R14 and the MSB R15.

If switching was carried out internally in the integrated circuit 5 , so that the tracking error signal and the focus error signal or other intermediate signals are output instead of the audio signals, the result is the image in FIG. 3. The channels LRCK and SDK48 are occupied in accordance with FIG. 2, while the information-carrying channel SDA48 now has the 8-bit focus error signal FE0 to FE7 instead of the audio signals in the section of the left audio signal and contains the 8-bit track error signal TE0 to TE7 in the right channel section. A different arrangement of the error signals in the audio channels is of course possible.

Fig. 4 shows the digital signal processor part 8 of the integrated circuit 5 in greater detail. The diode signals A + B, B + D, E and F coming from the outside are fed to a digital servo control circuit 18 via corresponding inputs 14 , 15 , 16 and 17 . The digital servo control circuit 18 calculates the focus control signal and the tracking control signal from the input signals, which is fed to an actuator 21 via outputs 19 , 20 . Furthermore, the digital servo control circuit has 18 outputs AAA, BBB, CCC to ZZZ, which represent the inputs of a multiplexer 22 . Furthermore, the digital signal processor 8 has audio inputs 23 , 24 for the left and right audio signals, which are fed to an audio oversampling and deemphasis filtering unit 25 . The audio R and audio L signals (right and left), which also represent inputs of the multiplexer 22 , are output from this unit 25 . The multiplexer 22 has two outputs 26 , 27 which lead into an audio-digital / analog converter 28 which, in the second embodiment shown, is arranged within the integrated circuit 5 . The corresponding audio signal is normally found in analog form at the outputs 29 , 30 of the audio D / A converter 28 . By means of software switching of the multiplexer 22 , however, any intermediate servo signal, such as the focus error signal tracking error signal, incoming diode signals, etc., can be output directly in analog fashion at the output of the audio digital / analog converter 28 . It should also be noted that the maximum audio channel rate depends on the digital / analog converter 6 . The sampling frequency of the digital servo is 44.1 KHz, which is exactly the same as the audio channel rate. Therefore, it is very easy to output certain intermediate signals in the audio channel instead of the audio data output signals. The maximum audio channel rate depends on the D / A converter 6 . For example, if the D / A converter 6 supports eight times oversampling, the maximum audio channel rate becomes larger, as shown below:
24 bit with 352.8 KHz sampling frequency (44.1 KHz × 8) for the left channel, and
24 bit with 352.8 KHz sampling frequency (44.1 KHz × 8) for the right channel.

In the digital signal processor 8 of the integrated circuit 5 shown in FIG. 3, the subgroups represented by block diagrams are preferably formed by programming the digital signal processor 8 , ie by software.

Claims (10)

1. Integrated circuit ( 1 ) for an optical turntable of a so-called "ON-CHIP" configuration, the integrated circuit ( 1 ) comprising an A / D converter ( 6 ), a digital signal processor ( 8 ) and a decoder ( 7 ) , characterized in that the integrated circuit ( 1 ) also has a changeover switch ( 22 ) with which intermediate signals, such as the focusing error signal or the tracking error signal, can be applied to the output channel (SDA48, 26 , 27 ) of the audio data. 2. Integrated circuit according to claim 1, characterized in that the changeover switch ( 22 ) is arranged in the digital signal processor ( 8 ). 3. Integrated circuit according to claim 2, characterized characterized that switching by choice corresponding IC parameters is made. 4. Integrated circuit according to one of the preceding claims, characterized in that the changeover switch ( 22 ) is program-controlled. 5. Integrated circuit according to claim 4, characterized in that the program control of the switch ( 22 ) is stored in the memory of the digital signal processor ( 8 ). 6. Integrated circuit according to one of the preceding claims, characterized in that the integrated circuit ( 1 ) further comprises a digital / analog converter ( 28 ) for converting the audio signals. 7. Integrated circuit according to one of the preceding claims, characterized in that the integrated circuit ( 1 ) further comprises an output unit ( 9 ) for outputting digital audio signals. 8. Integrated circuit according to one of the preceding claims, characterized in that the integrated circuit ( 1 ) further comprises a microprocessor unit ( 10 ). 9. CD player with an optical scanning device, wherein an integrated circuit ( 1 ) according to one of claims 1 to 8 is used. 10. CD player according to claim 9, characterized in that the optical scanning device ( 3 ) outputs six photodiode signals.