KR20090082997A - Digital video disc changer with multi-channel audio output function based on media oriented system transport protocols - Google Patents

Abstract

A DVD changer having multi-channel audio output function based on MOST protocol is provided to reduce distortion of image signal by transmitting multi-channel audio to each speaker through MOST network. A DVD changer having multi-channel audio output function based on MOST(Media Oriented System Transport) protocol comprises a DVD deck(110), a DSP(Digital Signal Processor,120), an MOST driver(150), and a video amp(170). The DVD deck outputs multi-channel audio data using I2S(Inter-IC sound) method together with a first word selection signal and a first clock signal. The DSP outputs encoding audio data in response to a second word selection signal and a second clock signal. The MOST driver receives the encoding audio data from the DSP and transmits it to an MOST optical connector. The video amp amplifies the analog video signal of NTSC and outputs the amplified signal to one or more monitors.

Description

Digital video disc changer with multi-channel audio output function based on media oriented system transport protocols}

The present invention relates to a DVD (Digital Video Disc) changer, and more particularly, to a DVD changer having a multi-channel audio output function.

In general, most DVD playback apparatuses have a two-channel audio output function including a left (L) channel and a right (R) channel. Recently, in order to allow a user to feel the sound of a multi-channel, for example, a DVD playback device having a multi-channel audio output function such as 5.1 channel has been developed. However, when a DVD playback device having a multi-channel audio output function is installed in a vehicle, the connection wiring between the respective devices becomes very complicated. Meanwhile, in addition to the DVD playback device, various multimedia devices such as a TV, a navigation device, an audio device, a digital radio, and the like are further installed in the vehicle. These multimedia devices require very complicated wiring work to be installed in a vehicle. Therefore, in order to simplify complicated wiring work, a data communication method using a Media Oriented System Transport (MOST) network is applied to a vehicle. When using the MOST network, only one fiber optic cable needs to be installed in the vehicle, which simplifies wiring. The multimedia devices can be connected to the MOST network respectively via the MOST interface devices. The MOST interface device follows a communication method based on the MOST protocol. The communication scheme based on the MOST protocol enables high-speed communication between multimedia devices and simplifies the connection structure between the multimedia devices. Due to these advantages of the MOST communication method, research on a vehicle DVD playback device capable of operating in connection with a MOST network is being conducted. However, the conventional DVD playback apparatus based on the MOST protocol developed to date can provide only two channels of audio output functions. In addition, a conventional DVD player based on the MOST protocol converts an analog video signal output from a DVD deck into digital video data, and converts the converted digital video data into digital data such as MPEG (Moving Picture Experts Group). Encoded by the method and transmitted to the MOST network. Thereafter, the video amplifier decodes the encoded video data received from the MOST network, converts the decoded video data back to an analog video signal, and outputs it to the monitor. However, due to the effects of noise generated during analog-to-digital (A / D) conversion and digital-to-analog (D / A) conversion, or encoding, the video signal to be displayed on a monitor (or display) Can be distorted. In addition, since the DVD reproducing apparatus must include devices for converting and encoding analog video signals, its manufacturing cost increases. On the other hand, when the monitor is installed near the rear magnet in the vehicle, in order to transmit the video signal from the DVD playback device to the monitor near the rear magnet, a MOST optical cable should be installed in the ceiling of the vehicle, but since the MOST optical cable is weak in heat, It is not suitable to transmit a signal over a MOST network.

Accordingly, a technical problem of the present invention is to amplify an analog video signal output from a DVD deck and transmit it to a monitor as it is, and to output MOST audio data of a multi-channel output from the DVD deck by an I2S (Inter-IC sound) interface method. The present invention provides a DVD changer having a multi-channel audio output function that can reduce distortion of a video signal and reduce manufacturing cost and time by transmitting to each speaker through a protocol based MOST network.

The DVD changer according to the present invention for achieving the above technical problem includes a DVD deck, a Digital Signal Processor (DSP), a Media Oriented System Transport (MOST) driver, and a video amplifier. The DVD deck stores a plurality of DVDs (Digital Video Discs), selects one of the plurality of DVDs in response to the DVD selection signal, reads the selected DVD, and outputs an analog video signal of the National Television Standards Committee (NTSC) standard. The multi-channel audio data is output together with the first word selection signal and the first clock signal by an inter-IC sound (I2S) method. The DSP receives multichannel audio data from the DVD deck in response to the first word select signal and the first clock signal, encodes the multichannel audio data, respectively, and responds to the second word select signal and the second clock signal. To output the encoded audio data. The MOST driver outputs a second word select signal and a second clock signal to the DSP in response to the control signal, receives encoded audio data from the DSP via a single data line, and transmits the encoded audio data to the MOST optical connector. The video amplifier amplifies the NTSC standard analog video signal and outputs it to at least one monitor. The frequency of the second clock signal is higher than the frequency of the first clock signal.

As described above, since the DVD changer according to the present invention amplifies the analog video signal output from the DVD deck and transmits it to the monitor as it is, the distortion of the video signal can be reduced, and the manufacturing cost thereof can be reduced. In addition, the DVD changer transmits the multi-channel audio data output from the DVD deck by the I2S (Inter-IC sound) interface method to each speaker through the MOST protocol based MOST network, thereby simplifying the connection wiring between the devices. Can be reduced, and its manufacturing cost and time can be reduced.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various forms, and only the present embodiments are intended to complete the disclosure of the present invention and to those skilled in the art. It is provided for complete information.

1 is a block diagram of a DVD changer according to an embodiment of the present invention. The DVD changer 100 includes a DVD deck 110, a digital signal processor (DSP) 120, a synchronous dynamic random access memory (SDRAM) 130, a flash memory 140, and a MOST driver 150. ), The microcomputer 160, and the video amplifier 170. The DVD deck 110 stores a plurality of digital video discs (DVDs) (not shown). The DVD deck 110 selects any one of the plurality of DVDs in response to the DVD selection signal SEL received from the microcomputer 160. Thereafter, the DVD deck 110 reads the selected DVD and outputs an analog video signal (VD) of NTSC (National Television Standards Committee) standard to the video amplifier 170. As a result, the video amplifier 170 amplifies the analog video signal VD of the NTSC standard, and outputs the amplified video signal AVD to the monitor 203 (see FIG. 2). The DVD deck 110 has an output function of an analog video signal of NTSC standard. The video amplifier 170 amplifies the NTSC standard analog video signal (VD) as it is, without converting or encoding the NTSC standard analog video signal (VD) output from the DVD deck 110 into a digital signal. Since the signal AVD is output to the monitor 203, the distortion of the video signal, which may occur due to the conversion and encoding of the video signal VD, may be reduced. In addition, since the DVD changer 100 does not need to include devices for converting and encoding the video signal VD, the manufacturing cost of the DVD changer 100 can also be reduced.

Meanwhile, the operation of the DVD deck 110 may be controlled by the control signal CTL1 output from the microcomputer 160. When reading the selected DVD, the DVD deck 110 reads not only the NTSC standard analog video signal (VD) but also audio data (SD0, SD1, SD2) of multi-channel (for example, 5.1-channel). The first word selection signal WS1 and the first clock signal SCLK1 are outputted to the DSP 120 by the IC sound. Here, the audio data SD0, SD1, and SD2 are digital data. When the DVD deck 110 outputs 5.1 channel audio data, the audio data SD0 is divided into audio data FLD of the front-L (left) channel and audio data FRD of the front-R channel. The audio data SD1 includes audio data RLD of a rear-L channel and audio data RRD of a rear-R channel. The audio data SD2 includes audio data CND of a center channel and audio data SWD of a sub-woofer channel. For example, when the DVD changer 100 is installed in a vehicle, the audio data FLD of the front-L channel corresponds to the audio signal to be output to the speaker installed at the front left side of the vehicle. In addition, the audio data FRD of the front-R channel corresponds to the audio signal to be output to the speaker installed on the front right side of the vehicle. The audio data RLD of the rear-L channel corresponds to the audio signal to be output to the speaker installed at the rear left side of the vehicle, and the audio data RRR of the rear-R channel is the audio signal to be output to the speaker installed at the rear right side of the vehicle. Corresponds to. The audio data CND of the center channel corresponds to the audio signal to be output to the speaker installed in the center portion of the vehicle, and the audio data SWD of the subwoofer channel corresponds to the audio signal to be output to the subwoofer speaker installed in the vehicle.

Referring to FIG. 3, an operation in which the DVD deck 110 outputs audio data SD0, SD1, and SD2 to the DSP 120 by I 2 S will be described in more detail. 3 is a timing diagram of signals related to an output operation of multi-channel audio data by the DVD deck 110. The DVD deck 110 outputs the first word select signal WS1 to a logic low (ie, '0'), and the audio data FLD, RLD of the front-L channel, the rear-L channel, and the center channel. , CND) respectively. In addition, the DVD deck 110 outputs the first word select signal WS1 at a logic high (ie, '1'), while the audio data FRD of the front-R channel, the rear-R channel, and the subwoofer channel is displayed. , RRD, SWD) are output respectively. In FIG. 3, only audio data SD0 including front-L channel FLD and front-R channel FRD is shown for simplicity of the drawing. Referring to FIG. 3, when the first word select signal WS1 is logic low, the DVD deck 110 outputs audio data FLD of the front-L channel as audio data SD0. Thereafter, when the first word select signal WS1 is logic high, the DVD deck 110 outputs the audio data FRD of the front-R channel as the audio data SD0.

Referring back to FIG. 1, in response to the first word select signal WS1 and the first clock signal SCLK1, the DSP 120 receives audio data SD0, SD1, and SD2 of the multi-channel from the DVD deck 110. ). Thereafter, the DSP 120 encodes the audio data SD0, SD1, and SD2 of the multichannel, respectively, and encodes the encoded audio data in response to the second word select signal WS2 and the second clock signal SCLK2. ESD0 to ESD3 are output to the MOST driver 150. Referring to FIG. 4, an operation in which the DSP 120 outputs encoded audio data ESD0 to ESD3 to the MOST driver 150 will be described in more detail. As referred to in FIG. 4, the period T1 of the first clock signal SCLK1 corresponds to four times the period T2 of the second clock signal SCLK2. As such, since the frequency of the second clock signal SCLK2 is higher than the frequency of the first clock signal SCLK1, the DSP 120 may transmit the multi-channel audio data SD0, SD1, and SD2 from the DVD deck 110. Compared to the time it takes to receive the signal, the time required for the DSP 120 to output the encoded audio data ESD0 to ESD3 to the MOST driver 150 is much shorter. That is, the time taken for the DSP 120 to output the encoded audio data (eg, ESD0) corresponds to one quarter of the time taken for the DSP 120 to receive the audio data SD0. In addition, although the DSP 120 needs three data lines to receive the multi-channel audio data SD0, SD1, and SD2 from the DVD deck 110, the DSP 120 may encode audio data ESD0 to. When outputting ESD3) to MOST driver 150, only a single data line DL is required. That is, since the DSP 120 performs an output operation in synchronization with the second clock signal SCLK2 having a higher frequency than the first clock signal SCLK1, the encoded audio data (eg, only through a single data line DL) may be used. ESD0 to ESD3) can be sufficiently output. As a result, the connection wiring between the DSP 120 and the MOST driver 150 may be simplified due to the reduction in the number of data lines.

Meanwhile, although FIG. 1 shows that the DSP 120 receives the second word select signal WS2 and the second clock signal SCLK2 from the MOST driver 150, the DSP 120 receives the second word select signal. The WS2 and the second clock signal SCLK2 may be output to the MOST driver 150. That is, the DSP 120 may output the encoded audio data ESD0 to ESD3 while outputting the second word select signal WS2 and the second clock signal SCLK2. The operation of the DSP 120 may be controlled by the control signal CTL2 output from the microcomputer 160. The DSP 120 may output the encoding completion signal END to the microcomputer 160 when the encoding of the multi-channel audio data SD0, SD1, and SD2 is completed. The SDRAM 130 is a memory required for the DSP 120 to operate, and stores data related to the operation of the DSP 120 such as a variable while the DSP 120 operates. The flash memory 140 stores an operation program PGM of the DSP 120.

The MOST driver 150 outputs the second word select signal WS2 and the second clock signal SCLK2 to the DSP 120 in response to the control signal CTL3 received from the microcomputer 160. The MOST driver 150 receives the encoded audio data ESD0 to ESD3 from the DSP 120 through the data line DL. The MOST driver 150 transmits the encoded audio data ESD0 to ESD3 to the MOST optical connector 201 (see FIG. 2). The MOST driver 150 supports communication between the external devices ED1 to EDK (K is an integer) and the microcomputer 160 connected to the MOST network 202. The MOST driver 150 receives the external input signal INSIG received from the MOST optical connector 201 and outputs the input signal INS to the microcomputer 160. At this time, the MOST driver 150 and the microcomputer 160 communicate with each other by the I2C (Inter-Integrated Circuit) method. That is, the MOST driver 150 outputs the clock signal SCK and the input signal INS to the microcomputer 160. Meanwhile, the MOST optical connector 201 converts an input signal INSIGF, which is an optical signal output from the input unit 204 connected to the MOST network 202, into an external input signal INSIG, which is an electrical signal, and outputs the MOST driver 150. To transmit.

The microcomputer 160 outputs the DVD selection signal SEL to the DVD deck 110 in response to the input signal INS received from the MOST driver 150. The microcomputer 160 outputs the control signal CTL3 to the MOST driver 150 in response to the encoding completion signal END received from the DSP 120. The microcomputer 160 may output a control signal CTL2 to the DSP 120 to control the operation of the DSP 120. The microcomputer 160 may communicate with external devices through the MOST driver 150. The microcomputer 160 may set setting values related to various operations of the DVD deck 110, the DSP 120, and the MOST driver 150, and control the operation of these devices.

Next, the operation of the DVD changer 100 will be described in more detail with reference to FIG. 2. FIG. 2 is a diagram illustrating all devices connected to the DVD changer and the MOST network shown in FIG. 1. The DVD changer 100 is connected to the MOST network 202 through the MOST optical connector 201. The DVD changer 100 is also connected to the monitor 203 via a signal line SL. An input unit 204 may be installed around the monitor 203. Optionally, the input unit 204 may be implemented as a touch screen of the monitor 203. Additional displays (not shown) may be further connected to the MOST network 202 in addition to the monitor 203. In addition, the external devices ED1 to EDK and the audio amplifier 205 are connected to the MOST network 202. The first to sixth speakers 206 to 211 are connected to the audio amplifier 205. The first to fifth speakers 206 to 210 may be installed at each of the front left and right sides of the vehicle, the rear left and right sides of the vehicle, and the center portion of the vehicle. The sixth speaker 211 may be installed in the vehicle. First, the user selects the desired DVD through the input unit 204 and selects play. The input unit 204 transmits an input signal INSIGF, which is an optical signal, to the MOST optical connector 201 through the MOST network 202 according to a user's input. The MOST optical connector 201 receives an input signal INSIGF, converts it into an external input signal INSIG, which is an electrical signal, and transmits it to the MOST driver 150. The MOST driver 150 receives the external input signal INSIG and outputs the clock signal SCK and the input signal INS to the microcomputer 160. The microcomputer 160 outputs the DVD selection signal SEL to the DVD deck 110 in response to the input signal INS. In response to the DVD selection signal SEL, the DVD deck 110 selects one of a plurality of DVDs stored therein and reads the selected DVD. The DVD deck 110 outputs an NTSC standard analog video signal (VD) to the video amplifier 170 while reading the DVD, and outputs audio data (SD0, SD1, SD2) of multiple channels (for example, 5.1 channels). ) Is output to the DSP 120 together with the first word selection signal WS1 and the first clock signal SCLK1. The video amplifier 170 amplifies the NTSC standard analog video signal VD and outputs the amplified NTSC standard analog video signal AVD to the monitor 203 through the signal line SL. As a result, a video image is displayed on the monitor 203.

The DSP 120 encodes audio data SD0, SD1, and SD2, respectively, and outputs an encoding completion signal END to the microcomputer 160. The microcomputer 160 outputs the control signal CTL3 to the MOST driver 150 in response to the encoding completion signal END. The MOST driver 150 outputs the second word signal WS2 and the second clock signal SCLK2 to the DSP 120 in response to the control signal CTL3. The DSP 120 outputs the encoded audio data ESD0 to ESD3 to the MOST driver 150 through the data line DL in synchronization with the second word signal WS2 and the second clock signal SCLK2. The MOST driver 150 receives the encoded audio data ESD0 to ESD3 and outputs the encoded audio data to the MOST optical connector 201. The MOST optical connector 201 converts the encoded audio data ESD0 to ESD3 into optical signals ESDF0 to ESDF3 and transmits them to the audio amplifier 205 through the MOST network 202. The audio amplifier 205 receives the optical signals ESDF0 to ESDF3 and converts them into encoded audio data ESD0 to ESD3. The audio amplifier 205 decodes and amplifies the encoded audio data ESD0 to ESD3 and outputs analog audio signals AU1 to AU6 to the first to sixth speakers 206 to 211, respectively.

The above embodiments are for explaining the present invention, and the present invention is not limited to these embodiments, and various embodiments are possible within the scope of the present invention. In addition, although not described, equivalent means will also be referred to as incorporated in the present invention. Therefore, the true scope of the present invention will be defined by the claims below.

1 is a block diagram of a DVD changer according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating all devices connected to the DVD changer and the MOST network shown in FIG. 1.

FIG. 3 is a timing diagram of signals related to an output operation of multi-channel audio data by the DVD deck shown in FIG. 1.

FIG. 4 is a timing diagram of first and second clock signals and multichannel audio data shown in FIG. 1.

<Explanation of symbols for main parts of drawing>

100: DVD changer 110: DVD deck

120: DSP 130: SDRAM

140: flash memory 150: MOST driver

160: microcomputer 170: video amplifier

Claims (5)

Store a plurality of DVDs (Digital Video Disc), select one of the plurality of DVDs in response to a DVD selection signal, read the selected DVD, and output an analog video signal of the National Television Standards Committee (NTSC) standard; A DVD deck for outputting multi-channel audio data together with a first word selection signal and a first clock signal by an inter-IC sound (I2S) scheme; In response to the first word select signal and the first clock signal, receive the multichannel audio data from the DVD deck, encode the multichannel audio data, respectively, a second word select signal and a second clock A digital signal processor (DSP) for outputting encoded audio data in response to a signal; In response to a control signal, outputting the second word select signal and the second clock signal to the DSP, receiving the encoded audio data from the DSP through a single data line to obtain a MOST (Media Oriented System Transport) optical connector Transfer to MOST driver; And A video amplifier for amplifying the NTSC standard analog video signal as it is and outputting it to at least one monitor; And the frequency of the second clock signal is higher than the frequency of the first clock signal. The method of claim 1, A microcomputer outputting the DVD selection signal in response to an input signal, and outputting the control signal in response to an encoding completion signal; And the DSP further outputs the encoding completion signal when completing the encoding of the multi-channel audio data. The method of claim 1, A flash memory storing an operation program of the DSP; And And a SDRAM for storing data related to the operation of said DSP while said DSP is operating. The method of claim 1, And the multi-channel audio data comprises 5.1 channel audio data. The method of claim 1, And the period of the first clock signal corresponds to four times the period of the second clock signal.

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