KR20190066790A - Media apparatus and control method for the same - Google Patents

Abstract

Provided is a media apparatus which can reproduce a high-quality sound. To this end, the media apparatus comprises: an audio signal receiving unit for receiving audio data from an audio source; and any one chip for processing the audio data. The any one chip includes: a clock generation unit for generating a clock signal and changing the pulse speed of the clock signal based on a format standard of the audio data; and a data modulation unit for modulating the audio data to be suitable for a data transmission specification of the any one chip, and transmitting a data packet including the audio data by synchronizing to the clock signal.

Description

[0001] MEDIA APPARATUS AND CONTROL METHOD FOR THE SAME [0002]

A media device for processing audio data, and a control method for the media device.

2. Description of the Related Art Recently, various media devices having an audio signal output function have been widely used. Such a media device is a device designed to record or reproduce an audio signal in the form of a digital file. Examples of the media device include an MP3 player, a portable phone (e.g., a smart phone), a portable multimedia player PMP), a television, a desktop, and the like.

A media device having an audio signal reproducing function has used a method of simply increasing the size of data of an audio signal in order to reproduce a high quality sound. However, when such a simple method is used, sound quality deterioration due to a headroom occurs do.

One embodiment disclosed is to provide a media device capable of reproducing high quality sound.

According to one aspect of the present invention, there is provided a media apparatus comprising: an audio signal receiving unit for receiving audio data from an audio source; And a chip for processing audio data, wherein one of the chips includes a clock generator for generating a clock signal and changing a pulse rate of the clock signal based on a format specification of the audio data, And transmits the data packet including the audio data in synchronization with the clock signal.

A first clock generator for generating, as a first clock signal, an L signal indicating that data of the L channel is transmitted and an R signal indicating that the data of the R channel are transmitted so that the audio data of the stereo type is transmitted; And a second clock generator for generating a second clock signal.

The clock generator may increase the pulse rate when the format specification of the audio data is larger than the data transmission specification of any one of the chips.

The clock generating unit can increase the pulse rate twice when the format specification of the audio data is larger than the data transmission specification of any one of the chips, but is less than twice the data transmission specification.

The data modulator may allocate a part of the data packet as a parity area, transmit information on the format specification of the audio data in the parity area, and transmit the audio data in the remaining area of the data packet excluding the parity area.

The data modulator can allocate a part of the data packet as a parity area when the format specification of the audio data is larger than the data transmission specification of any one of the chips but less than twice the data transmission specification.

The data modulator may allocate the first end of the data packet as a parity area.

The data modulator may allocate the last end of the data packet as a parity area.

The data modulator can divide and transmit the data packet when the format specification of the audio data is larger than the data transmission specification of any one chip.

Another chip for receiving a clock signal and a data packet with a changed pulse rate from one chip while the other chip is capable of reducing the pulse rate of the clock signal and reducing the audio data according to the format specification of the audio data .

The other chip may further modulate audio data into an analog audio signal, and the media device may further include an acoustic unit that outputs sound based on the analog audio signal.

According to another aspect, a method of controlling a media device includes receiving audio data from an audio source; Modifying the pulse rate of the clock signal based on the format specification of the audio data and modulating the audio data in accordance with the data transmission specification of the one chip; And transmitting the clock signal at a changed pulse rate, and transmitting the data packet including the audio data in synchronization with the clock signal.

The step of transmitting the clock signal includes the steps of transmitting, as a first clock signal, an L signal indicating that data of the L channel is transmitted and an R signal indicating that the data of the R channel are transmitted so that the audio data of the stereo type is transmitted, And transmitting a second clock signal for synchronization of the step of transmitting the second clock signal.

The step of changing the pulse rate of the clock signal may include the step of increasing the pulse rate if the format specification of the audio data is larger than the data transmission specification of either chip.

The step of changing the pulse rate of the clock signal may include the step of doubling the pulse rate if the format specification of the audio data is larger than the data transmission specification of any one chip but less than twice the data transmission specification.

The step of modulating the audio data includes a step of allocating a part of the data packet as a parity area, and the step of transmitting the data packet includes transmitting information on the format specification of the audio data in the parity area, And transmitting the audio data in the remaining areas.

The step of allocating a part of the data packet as a parity area includes the step of allocating a part of the data packet as a parity area when the format specification of the audio data is larger than the data transmission specification of either chip but less than twice the data transmission specification can do.

The step of transmitting the data packet may include a step of dividing and transmitting the data packet when the format specification of the audio data is larger than the data transmission specification of any one of the chips.

The control method of the media device may further include reducing the pulse rate of the clock signal and reducing the audio data according to the format specification of the audio data.

A method of controlling a media device includes: modulating audio data into an analog audio signal; And outputting sound based on the analog audio signal.

According to the above-mentioned problem solving means, a media device having a data transmission specification can transmit audio data having a variety of format specifications compared to conventional ones, thereby enabling a user to acquire high quality sound.

Further, according to the above-mentioned problem solving means, data loss due to headroom can be prevented.

1 is an exemplary view of a media device according to an embodiment.
2 is a block diagram illustrating a detailed configuration of a media device according to an embodiment.
3 is a diagram illustrating an example of a control unit included in a media device according to an exemplary embodiment of the present invention.
4 is a graph illustrating a waveform of a digital signal generated by the first chip of the media device according to an exemplary embodiment.
5 is a diagram illustrating two examples of data packets transmitted by the data modulation unit.
FIGS. 6 to 9 are diagrams for explaining that parity regions are variously allocated when a data packet is divided and transmitted.
10 is an operational flowchart of a method of controlling a media device according to an embodiment.

Like reference numerals refer to like elements throughout the specification. The present specification does not describe all elements of the embodiments, and redundant description between general contents or embodiments in the technical field of the present invention will be omitted. As used herein, the terms 'part, module, member, block' may be embodied in software or hardware, and in accordance with the embodiments, a plurality of subsystems, modules, It is also possible for the term " part, module, member, block "

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Throughout the specification, when a member is located on another member, it includes not only when a member is in contact with another member but also when another member exists between the two members.

The terms first, second, etc. are used to distinguish one element from another, and the elements are not limited by the above-mentioned terms.

The singular forms " a " include plural referents unless the context clearly dictates otherwise.

Hereinafter, embodiments will be described with reference to the accompanying drawings.

1 is an exemplary view of a media device according to an embodiment.

An example of the media device 100 shown in Fig. 1 is a television 104. Fig. The television is basically a video device, but when viewing video content through the television 104, the quality of the video as well as the quality of the video can be an important point of appreciation. Therefore, audio signal processing for outputting high-quality audio in the television 104 is as important as video signal processing. The television 104 may be provided with a speaker. The media device 100 according to an exemplary embodiment is not limited to the television 104, and may include various devices requiring audio signal processing such as a professional audio device for music listening or a PC-FI utilizing a notebook / desktop.

2 is a block diagram illustrating a detailed configuration of a media device according to an embodiment.

Referring to FIG. 2, the media device includes an audio signal receiving unit 110, a communication unit 120, a controller 130, and an audio unit 140.

The audio signal receiving unit 110 receives audio content including audio data from an audio source and outputs the received audio data to the control unit 130.

The audio signal receiving unit 110 may include a terminal 111 for receiving audio content from an audio source and a tuner 112 for receiving the broadcast signal and tuning the received broadcast signal.

The terminal 111 of the audio signal receiving unit 110 may be connected to an audio source through a cable and may receive audio content including audio data from an audio source. The audio content is received in the form of a data stream, and the data stream of the audio content (hereinafter referred to as 'content data') can be generated by encoding the audio data.

The terminal 111 of the audio signal receiving unit 110 includes a component (YPbPr / RGB) terminal and a composite video blanking and sync (CVBS) terminal for receiving analog data for receiving video data together with audio data . The terminal 111 of the audio signal receiving unit 110 may include a High Definition Multimedia Interface (HDMI) terminal for receiving digital image frame data together with audio data. The terminal 111 of the audio signal receiving unit 110 may also include a universal serial bus (USB) terminal for receiving audio data from an external storage medium (e.g., a USB drive).

The tuner 112 of the audio signal receiving unit 110 receives a broadcast signal from a broadcast receiving antenna or a cable and extracts a broadcast signal of a channel selected by the user in the broadcast signal. For example, the tuner 112 may transmit a television broadcast signal having a frequency corresponding to a channel selected by the user among the television broadcast signals of various frequencies received through the broadcast receiving antenna, and may block a television broadcast signal having a different frequency . The television broadcast signal can be generated by modulating the data stream of the content, and the media device 100 can generate the content data by demodulating the television broadcast signal.

As described above, the audio signal receiving unit 110 can receive the audio content from the audio source, and output the audio content to the control unit 130.

The communication unit 120 can exchange data with an audio source or an external device through a communication network. For example, the communication unit 120 can receive audio content from an audio source or receive information on audio content from an external device. The information on the audio content may include the title of the content, the type of the content, the genre of the content, and the like as information on the content itself.

At this time, the communication network may include both wired and wireless communication networks. The wired communication network includes a communication network such as a cable network or a telephone network, and the wireless communication network may include a communication network for transmitting and receiving signals through radio waves. The wireless communication network may also include an access point (AP), which may be wirelessly connected to the media device 100 and wired to a wired communication network.

The communication unit 120 may include a wired communication module 121 for exchanging data with an audio source and an external device, and a wireless communication module 122 for wirelessly exchanging data with an audio source and an external device.

The wired communication module 121 can be connected to a wired communication network and communicate with an audio source through a wired communication network. For example, the wired communication module 121 may connect to a wired communication network through an Ethernet (IEEE 802.3 standard) and receive data from an audio source and an external device via a wired communication network.

The wireless communication module 122 may communicate wirelessly with a base station or an access point (AP), and may access a wired communication network through a base station or an access point. The wireless communication module 122 may also communicate with audio sources and external devices connected to a wired communication network via a base station or access point. For example, the wireless communication module 122 wirelessly communicates with an access point (AP) using a WiFi (TM) (IEEE 802.11 technology standard) or a wireless communication module such as CDMA, WCDMA, GSM, Long Term Evolution To communicate with the base station. The wireless communication module 122 may also receive data from an audio source and an external device via a base station or access point.

In addition, the wireless communication module 122 may communicate wirelessly with the audio source and the external device. For example, the wireless communication module 122 may wirelessly communicate with an audio source and an external device using WiFi, Bluetooth (TM), IEEE 802.15.1 technology standard, ZigBee (TM), IEEE 802.15.4 technology standard Data can be received.

As described above, the communication unit 120 can receive information on the audio content and the audio content from the audio source and the external device through the wired communication module 121 and the wireless communication module 122, The control unit 130 can output information on the audio content and audio content received through the communication module 122 to the control unit 130. [

The control unit 130 may control the audio signal receiving unit 110, the communication unit 120, and the sound unit 140. For example, when a user input for selecting an audio source is received, the control unit 130 may control the audio signal receiving unit 110 and the communication unit 120 to receive content data from the selected audio source. In addition, when a user input for image adjustment and sound adjustment is received, the controller 130 may control the display unit 150 and the sound unit 140 to adjust the image and sound.

The control unit 130 may process the audio data received by the audio signal receiving unit 110 and the communication unit 120. For example, the control unit 130 may decode the content data to restore the audio data, and may output the restored audio data to the sound unit 140. [ In addition, the controller 130 may decode the content data to recover the audio data, and may process the audio data to generate an analog audio signal (hereinafter, referred to as 'audio signal').

The controller 130 according to one embodiment may include one or more chips, which may be various integrated circuits for processing digital signals, such as a processor 131, a memory 132, and the like.

The memory 132 may store programs and data for controlling the configurations contained in the media device 100 and may temporarily store control data issued while controlling the configurations included in the media device 100. [

The memory 132 stores a program and data for decoding the content data received by the audio signal receiving unit 110 or the communication unit 120 and temporarily stores the audio data to be issued during the decoding of the content data have.

The memory 132 may include a nonvolatile memory such as a read only memory and a flash memory for storing data for a long time, an S-RAM (Static Random Access Memory, S-RAM) for temporarily storing data, a D And a dynamic random access memory (RAM).

The processor 131 may generate a control signal for controlling the audio signal receiving unit 110, the communication unit 120, and the sound unit 140.

The processor 131 includes a microprocessor, a DSP, and the like, and may be provided as one or more chips.

The processor 131 may receive the content data from the audio signal receiving unit 110 or the communication unit 120. [ The processor 131 may decode the content data according to the program and data stored in the memory 132, and may restore the audio data.

The processor 131 may include an arithmetic circuit for performing a logical operation and an arithmetic operation, a storage circuit for storing arithmetic data, and the like.

The acoustic unit 140 may include an amplifier 141 for amplifying sound based on the audio data received from the control unit 130 and a speaker 142 for audibly outputting the amplified sound.

The control unit 130 may process audio data and convert the audio data into an audio signal. The amplifier 141 may amplify the audio signal output from the control unit 140.

The speaker 142 can convert the audio signal amplified by the amplifier 141 into sound (sound wave). For example, the speaker 142 may include a thin film that vibrates according to an electrical audio signal, and a sound wave may be generated by the vibration of the thin film.

As described above, the media device 100 can receive content including audio data from various audio sources, and output video and audio included in the content.

Hereinafter, a process of processing audio data by the media device 100 according to an embodiment will be described.

3 is a diagram illustrating an example of a control unit included in a media device according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the controller 130 may receive content data from the audio signal receiver 110, and may process the content data to generate an audio signal. The control unit 130 may output the audio signal generated from the content data to the audio unit 140. [

The control unit 130 may include a decoder 210, a first chip 220, and a second chip 230. The decoder 210, the first chip 220, and the second chip 230 may each be implemented as a separate chip comprising a processor, or as a separate chip comprising a processor and a memory. The processors of the chips 220 and 230 of the control unit 130 according to the embodiment may be configured to execute applications stored in a memory or to exchange audio data So that the modulated audio data can be exchanged with each other.

The decoder 210 may decode the content data to recover the audio data. The content data may be compressed / encoded by various compression / encoding standards. For example, the content data may be compressed / encoded using an audio compression standard such as AAC (Advanced Audio Coding), MPEG-H 3D Audio, and the like.

The decoder 210 may recover audio data from the content data using an audio compression standard.

In addition, the decoder 210 may output the audio data to the first chip 220. The audio data output to the first chip 220 may be formed in any format standard. Here, the format specification indicates a unit of the data size in which the audio data is divided. For example, when the format standard is 24 bits, the audio data is formed in the form of a packet in units of 24 bits.

The first chip 220 and the second chip 230 may each include a processor 131 and may have the same sampling frequency and data transmission specifications. Here, the same data transmission specification indicates that the data size (number of bits) that can be transmitted / received per "clock" and the data transmission specification are the same means that the data size (number of bits) , And the sampling frequency represents the transmission / reception speed of data. Therefore, if the first chip 220 and the second chip 230 have any sampling frequency and data transmission specification, then the data transmission specification is not changed even if the sampling frequency is increased or decreased. The first chip 220 and the second chip 230 of the first and second chips 100 and 100 may not only transmit and receive audio data of a format standard corresponding to the data transmission specification but also increase the sampling frequency, Audio data having a standard can be transmitted and received.

For example, when the first chip 220 and the second chip 230 have a data transmission specification for transmitting and receiving 24 bits for one clock and the format specification of the audio data is 32 bits, Bit data packets can be transmitted / received by doubling the sampling frequency so that two clocks are transmitted during the first chip 220. Since the first chip 220 includes 32-bit audio data in the 48-bit data packet, Can be transmitted. Here, the unit time means the time taken for the "one" clock included in the signal to be transmitted when the signal is transmitted at the original sampling frequency preset in the manufacturing step.

The first chip 220 according to an embodiment includes a first clock generating unit 221, a second clock generating unit 222 and a data modulating unit 223, and the second chip 230 includes a first A clock demodulation unit 231, a second clock demodulation unit 232, and a data demodulation unit 233.

4 is a graph illustrating a waveform of a digital signal generated by the first chip of the media device according to an exemplary embodiment. The abscissa in Figs. 4 to 9 described below represents time, and the ordinate represents a digital signal having a pulse of 0 or 1.

The first clock generator 221 generates the first clock signal LRCK and outputs the first clock signal LRCK in accordance with a predetermined sampling frequency (i.e., according to a predetermined first pulse rate h [Hz]). To the second chip (230). Here, the first clock signal LRCK represents a digital signal including a pulse sequence of 0 and 1 periodically transmitted according to the sampling frequency.

The first clock generating unit 221 generates a first clock signal LRCK indicating that the data of the L channel is transmitted as the first clock signal LRCK in order to transmit the stereo audio data, (Hereinafter referred to as R signal) as 0 or 1, respectively. When audio data of a stereo type is transmitted, when the L signal and the R signal included in one clock (CLK) are respectively transmitted, the data modulator 223 can transmit the same audio data as data for the L channel and the R channel, respectively When mono type audio data is transmitted, when the L signal and the R signal included in one clock (CLK) are respectively transmitted, the data modulator 232 transmits the same or different audio data to the L channel and the R channel Respectively.

Hereinafter, for convenience of explanation, it is assumed that stereo type audio data is transmitted, 0 is transmitted as an L signal, and 1 is transmitted as an R signal.

The first clock generator 221 can change the sampling frequency of the first clock signal LRCK, that is, the first pulse rate, according to the format of the audio data.

Specifically, when the format specification of the audio data conforms to the data transmission specification of the first chip 220 (that is, when the format specification of the audio data is the data transmission of the first chip 220) Specification), the L signal and the R signal can be transmitted at the first pulse rate (h [Hz]) set in advance in the manufacturing step.

However, if the format specification of the audio data does not match the data transmission specification of the first chip 220 (i.e., the format specification of the audio data is the data transmission of the first chip 220) Specification), the first pulse rate h [Hz] can be increased. In this case, the first clock generating unit 221 may increase the first pulse rate N times (N is a natural number) according to the format of the audio data.

For example, when the transmission specification of the first chip 220 is g [bit] and the audio data has a format specification of g [bit] or less, the first clock generation section 221 generates a clock To transmit the first pulse signal (LRCK). Accordingly, audio data having a size of g [bit] or less can be transmitted for a unit time T. [

However, if the audio data has a format specification exceeding g [bit] to 2 * g [bit], the first clock generating section 221 can increase the first pulse rate to 2 * h [Hz] And may transmit the first pulse signal LRCK according to the increased first pulse rate. Accordingly, audio data having a size exceeding g [bit] and equal to or smaller than 2 * g [bit] can be transmitted for a unit time T. [

That is, assuming that N is a natural number of 2 or more, if the transmission specification of the first chip 220 is g [bit] and the audio data is in a format of (N-1) * g [ Specification, the first clock generator 221 can increase the first pulse rate to N * h [Hz] and transmit the first pulse signal LRCK according to the increased first pulse rate . Accordingly, audio data having a size greater than (N-1) * g [bit] and equal to or smaller than N * g [bit] can be transmitted for a unit time T. [

The second clock generator 222 generates the second clock signal SCLK. The second clock signal SCLK represents a digital signal including a pulse sequence of 0 and 1 periodically transmitted according to a preset frequency. The second clock generator 222 generates a second clock signal SCLK 2 clock signal SCLK, but can change the second pulse rate according to the format specification of the audio data. In this case, the second clock generating unit 222 may generate the second clock signal SCLK based on the first clock signal LRCK generated by the first clock generating unit 221. [

For example, when the transmission specification of the first chip 220 is g [bit] and the audio data has a format specification of g [bit] or less, the second clock generation section 222 generates a second clock signal And can transmit the second pulse signal SCLK. Accordingly, audio data having a size of g [bit] or less can be transmitted for a unit time T. [

However, if the audio data has a format specification exceeding g [bit] to 2 * g [bit], the second clock generating section 222 can increase the second pulse rate by two times, The second pulse signal SCLK can be transmitted according to the speed. Accordingly, audio data having a size exceeding g [bit] and equal to or smaller than 2 * g [bit] can be transmitted for a unit time T. [ In this case, the second clock generating unit 222 may increase the second pulse rate by a factor of two based on the first pulse rate of the first clock signal LRCL which has been doubled.

That is, assuming that the transmission specification of the first chip 220 is g [bit] and the audio data is more than (N-1) * g [bit] and N * g [bit] The second clock generator 222 can increase the second pulse rate N times and transmit the second pulse signal SCLK according to the increased second pulse rate. Accordingly, audio data having a size greater than (N-1) * g [bit] and equal to or smaller than N * g [bit] can be transmitted for a unit time T. [ In this case, the second clock generator 222 may increase the second pulse rate N times based on the first pulse rate of the N-fold increased first clock signal LRCL.

The data modulator 223 modulates the audio data received from the decoder 210 in accordance with the data transmission specification of the first chip 220 and outputs the modulated audio data in synchronization with the second clock signal SCLK to the second To the chip 230.

For example, when the data transmission specification of the first chip 220 is g [bit] and the audio data has a format specification of g [bit] or less, the data modulating section 223 performs one When the L signal is transmitted, audio data having a size of g [bit] or less is transmitted to the second chip 230 in a g [bit] data packet. When one R signal is transmitted, To the second chip (230).

Specifically, when the L signal is transmitted by the first clock generator 221, the data modulator 223 outputs g [bit] every time a clock of the second clock signal SCLK is generated based on the transmission start point of the L signal, And transmits the following audio data bit by bit. Here, transmission in units of bits may indicate transmission of audio data divided into 1 [bits].

When the R signal is transmitted by the first clock generator 221, the data modulator 233 modulates the previous L signal whenever a clock of the second clock signal SCLK is generated based on the transmission start point of the R signal And transmits the same audio data as that transmitted in bit units.

When the L signal is transmitted by the first clock generator 221 using the right alignment method, the data modulator 223 modulates the L signal in the g [bit] data packet in the reverse order And transmits the data packet in bit units. When the R signal is transmitted, the same audio data as that transmitted for the previous L signal in the reverse order with respect to the last time point of the R signal in one data packet is sorted The data packet may be transmitted on a bit-by-bit basis, depending on the data processing method supported by the first chip 220. For example, I2S, Left-Justified, or Right-Justified may be a data processing method supported by the first chip 220. [ Hereinafter, for convenience of explanation, an I2S method of transmitting audio data based on a transmission start point of an L signal or an R signal will be described as an example.

On the other hand, when the data transmission specification of the first chip 220 is g [bit] and the audio data has a format standard exceeding g [bit] and 2 * g [bit] When the L signal is transmitted twice during the unit time T as the speed of the signal LRCK increases by two times, the audio data is transmitted to the second chip 230 in the two g [bit] data packets, And transmits two g [bit] data packets to the second chip 230 in the same manner as when the L signal is transmitted, when two R signals are transmitted during the period (T).

That is, the data modulating unit 223 modulates the format specification of the first chip 220 with the data transmission specification of g [bit] and the audio data of (N-1) * g [bit] , If N L signals are transmitted for a unit time T as the speed of the first clock signal LRCK increases N times, the audio data is loaded into the N g [bit] data packets, If N R signals are transmitted during a unit time T, N g [bit] data packets are transmitted to the second chip 230 in the same manner as when L signals are transmitted.

On the other hand, since the data modulator 223 can transmit a data packet of N * g [bit] size for a unit time T, the d [bit] size The data packet of size N * g [bit] includes the remaining bits in addition to d [bit] occupied by the audio data.

Accordingly, when the audio data has a format specification of d [bit] size with g [bit] and less than 2 * g [bit], data modulator 233 according to an embodiment additionally supplies information other than audio data to data packet To the second chip 230. [0050]

5 is a diagram illustrating two examples of data packets transmitted by the data modulation unit.

5, when the audio data has a format specification of d [bit] size larger than g [bit] and less than 2 * g [bit], the first clock generator 221 and the second clock generator 222 The data modulator 223 increases the speed of the first clock signal and the second clock signal by a factor of two so that the size of a data packet that the data modulator 223 can transmit for a unit time T increases by two times 2 * g [bit].

The data modulator 223 of the first chip 220 according to the embodiment of the present invention includes an area (bit [d] [bit]) for transmitting audio data to a part of a data packet PA transmittable during a unit time T, And a parity area (bit; p [bit]) can be allocated to the remaining part.

The parity area p [bit] is an area for transmitting information on the protocol. For example, the parity area p [bit] may contain information on the format specification of the audio data, information on the transmission specification of the first chip 220, The data modulator 223 can allocate the parity area p [bit] to the last stage of the data packet PA as shown at the top of FIG. 5, and at the first stage The allocation position of the parity area (p [bit]) is not particularly limited.

If the format of the audio data is larger than the data transmission specification of the first chip 220, the speed of the first clock signal LRCK increases. Therefore, the first clock signal LRCK, which is transmitted during the unit time T, The length of the pulse (L signal or R signal) of the data packet PA is shortened and the number of pulses is increased. Accordingly, the data modulator 223 can divide the data packet PA and transmit it to the second chip 230.

FIGS. 6 to 9 are diagrams for explaining that parity regions are variously allocated when a data packet is divided and transmitted.

Referring to FIG. 6, the data modulator 223 can allocate the parity area p to the first stage of one of the divided packets PA1 and PA2 of the divided data packets (hereinafter, referred to as PA1 and PA2). Thus, the remaining area d1 of the divided packet PA1 to which the parity area p is allocated and the entire area d2 of the divided packet PA2 other than the parity area p are allocated as areas for transmitting audio data.

However, since the L channel and the R channel are mutually independent when the stereo audio data is transmitted, the data modulator 223 transmits the data and the R signal while the data modulator 223 transmits the L signal, 223 are also independent of each other. Therefore, the data modulator 223 can transmit the divided packet PA1 to which the parity area p is allocated as data of the L channel and the R channel, respectively, Packet PA2 as data of the L channel and the R channel, respectively. When stereo audio data is transmitted as described above, each divided packet transmitted as data of the L channel and the R channel for one clock period may be the same.

Referring to Fig. 7, the data modulator 223 may allocate the parity area p to the last stage of another divided packet PA2. Thus, the remaining area d2 of the divided packet PA2 to which the parity area p is allocated and the entire area d1 of the divided packet PA1 are allocated as areas for transmitting audio data.

When audio data of the stereo type is transmitted, the data modulator 223 can transmit the divided packet PA1, to which the parity area p is not allocated, as data of the L channel and the R channel, respectively, and transmits the first clock signal Another divided packet PA2 to which the parity area p is allocated at the next clock of the LRCK can also be transmitted as data of the L channel and the R channel, respectively.

8, the data modulator 223 may allocate the parity area p to the first stage of a divided packet PA1 and the first stage of another divided packet PA2, respectively. The remaining area d1 of one partitioned packet PA1 allocated the first parity area p1 and the remaining area d2 of another divided packet PA2 allocated the second parity area p2, Is allocated as an area for transmitting audio data.

When the audio data of the stereo type is transmitted, the data modulator 223 can transmit any one of the divided packets PA1 as the data of the L channel and the R channel, respectively. At the next clock of the first clock signal LRCK And another divided packet PA2 as data of the L channel and the R channel, respectively.

9, the data modulator 223 may allocate the parity area p to the last stage of one of the divided packets PA1 and the last stage of the other divided packet PA2, respectively. The remaining area d1 of one partitioned packet PA1 allocated the first parity area p1 and the remaining area d2 of another divided packet PA2 allocated the second parity area p2, Is allocated as an area for transmitting audio data.

When the audio data of the stereo type is transmitted, the data modulator 223 can transmit any one of the divided packets PA1 as the data of the L channel and the R channel, respectively. At the next clock of the first clock signal LRCK And another divided packet PA2 as data of the L channel and the R channel, respectively.

In addition, the data modulator 223 can allocate the parity area p and the area d to which the audio data is to be transmitted at various positions of the divided packets PA1 and PA2. In the above example, No.

The data modulator 223 includes protocol information in the parity area p allocated as described above and transmits the data packet PA containing the audio data to the second chip 230 in the area d to which the audio data is to be transmitted. Lt; / RTI >

Referring again to FIG. 3, the first clock demodulating unit 231 of the second chip 230 changes the speed of the first clock signal to a predetermined sampling frequency (that is, a first pulse To the speed (h [Hz]).

In this case, the first clock demodulator 231 can determine the format specification of the audio data transmitted based on the protocol information in the parity area, and also determine the transmission specification of the first chip 220.

For example, when the transmission specification of the first chip 220 is g [bit] and the audio data has a format specification of g [bit] or less, the first clock signal generated by the first clock generator 221 The first clock demodulator 231 can output the first clock signal as it is.

However, when the audio data has a format standard of g [bit] to 2 * g [bit] or less, the speed of the first clock signal generated by the first clock generator 221 is twice The first clock demodulating unit 231 can reduce the speed of the first clock signal to a predetermined sampling frequency by reducing the speed of the first clock signal by 1/2.

That is, assuming that N is a natural number of 2 or more, if the transmission specification of the first chip 220 is g [bit] and the audio data is in a format of (N-1) * g [ The first clock demodulating unit 231 may set the speed of the first clock signal to a value obtained by multiplying the speed of the first clock signal by It is possible to reduce the speed of the first clock signal to a predetermined sampling frequency by decreasing by 1 / N times.

The second clock demodulator 232 also reduces the speed of the second clock signal to the second pulse rate when the speed of the second clock signal is changed.

In this case, the second clock demodulation unit 232 can determine the format specification of the audio data transmitted based on the protocol information in the parity area, and also determine the transmission specification of the first chip 220. The second clock demodulating unit 232 may demodulate the second clock signal SCLK based on the first clock signal LRCK demodulated by the first clock demodulating unit 231. [

For example, when the transmission specification of the first chip 220 is g [bit] and the audio data has a format standard of g [bit] or less, the second clock signal generated by the second clock generator 222 The second clock demodulation unit 232 can output the second clock signal as it is. In this case, the second clock demodulating unit 232 can directly output the second clock signal based on the first pulse rate of the first clock signal LRCK output by the first clock demodulating unit 231 .

However, when the audio data has a format standard of g [bit] and 2 * g [bit] or less, the speed of the second clock signal generated by the second clock generation unit 222 is lower than a predetermined second pulse rate The second clock demodulating unit 232 can reduce the speed of the second clock signal to a predetermined second pulse speed by reducing the speed of the second clock signal by a factor of two. In this case, the second clock demodulator 232 multiplies the second clock signal by 1/2 based on the first pulse rate of the first clock signal LRCK reduced by 1/2 by the first clock demodulator 231, 2 times.

That is, assuming that N is a natural number of 2 or more, if the transmission specification of the first chip 220 is g [bit] and the audio data is in a format of (N-1) * g [ The first clock demodulating unit 231 may set the speed of the first clock signal to a value obtained by multiplying the speed of the first clock signal by It is possible to reduce the speed of the first clock signal to a predetermined sampling frequency by decreasing by 1 / N times. In this case, the second clock demodulator 232 multiplies the second clock signal by 1 / N times by the first clock demodulator 231 based on the first pulse rate of the first clock signal LRCK, N times.

The data demodulator 233 reduces the data packets transmitted according to the data transmission specifications of the first chip 230 and the second chip 230 back to the format specification of the audio data. For example, when a 24-bit divided packet is transmitted twice for a unit time and a 48-bit data packet is transmitted, the data demodulator 233 determines whether the format specification of the audio data is 32 bits based on the protocol information included in the parity area And audio data can be extracted from the data packet according to the format specification.

The data demodulator 233 processes the extracted audio data, generates an analog audio signal, and outputs the analog audio signal to the audio unit 140.

At least one component may be added or deleted corresponding to the capabilities of the components of the media device 100 shown in Figures 2 and 3. It will be readily understood by those skilled in the art that the mutual position of the components can be changed corresponding to the performance or structure of the system.

2 and 3 may be software and / or hardware components such as field programmable gate arrays (FPGAs) and application specific integrated circuits (ASICs).

10 is an operational flowchart of a method of controlling a media device according to an embodiment.

The first chip of the media device according to an exemplary embodiment receives audio data from another device such as a decoder (1110), and compares the format specification of the audio data with a data transmission specification of the first chip (1120).

Here, the format specification indicates a unit of the data size in which the audio data is divided, and the data transmission specification indicates the size of data that can be transmitted while the clock of the first clock signal occurs once.

If the format specification of the audio data is equal to or less than the data transmission specification of the first chip included in the media device ("No" in 1120), the first chip is set in advance on the second chip included in the media device Transmits a first clock signal at a first pulse rate, transmits a second clock signal at a second predetermined pulse rate, and transmits a data packet including audio data (1140).

However, if the format specification of the audio data is smaller than the data transmission specification of the first chip included in the media device, the first chip allocates a part of the data packets that can be transmitted during the unit time as an area for transmitting audio data, Can be allocated as a parity area for transmitting information on a format standard of audio data.

The second chip can receive the first clock signal, the second clock signal, and the data packet, determine the format specification of the audio data based on the format specification information of the audio data contained in the parity area, To generate an audio signal, and output the generated audio signal to the acoustic unit.

On the other hand, if the format specification of the audio data is larger than the data transmission specification of the first chip included in the media device ("Yes" in 1120), the first chip increases the first pulse rate of the first clock signal, The second pulse rate of the clock signal is also increased (1130).

Specifically, when the format specification of the audio data is larger than the data transmission specification of the first chip but less than twice the data transmission specification, the first chip increases the first pulse rate and the second pulse rate by two times, respectively.

Assuming that N is a natural number of 3 or more, if the format specification of the audio data is (N-1) times larger than the data transmission specification of the first chip and is N times or less than the data transmission specification, The speed and the second pulse rate can be increased by N times, respectively.

Then, the first chip of the media device transmits a first clock signal at an increased first pulse rate to the second chip, transmits a second clock signal at an increased second pulse rate, (1140).

However, if it is assumed that N is a natural number of 2 or more and the format specification of the audio data is N-1 times or more than N-1 times the data transmission specification of the first chip, Data can be allocated as an area for transmission and the remaining part can be allocated as a parity area for transmitting information on the format specification of audio data.

However, if the format specification of the audio data is larger than the data transmission specification of the first chip included in the media device ("Yes" in 1120), a plurality of divided packets are transmitted during a unit time, A parity area may be allocated to at least one of the divided packets, and the remaining area of the divided packet to which the parity area is allocated and the entire area of the other divided packets to which the parity area is not allocated may be allocated as an area for audio data transmission.

The first chip may transmit the first clock signal and the second clock signal to the second chip, transmit the protocol information including the format specification information of the audio data in the parity area, and transmit the audio data in the remaining area.

The second chip can receive the first clock signal and the second clock signal, reduce the original clock rate to a predetermined original pulse rate, receive a plurality of divided packets, and reduce the audio data according to the format specification of the audio data. The reduced audio data can be converted into an analog audio signal and output to the acoustic unit.

The disclosed embodiments may be embodied in the form of a recording medium storing instructions executable by a computer. The instructions may be stored in the form of program code and, when executed by a processor, may generate a program module to perform the operations of the disclosed embodiments. The recording medium may be embodied as a computer-readable recording medium.

The computer-readable recording medium includes all kinds of recording media in which instructions that can be decoded by a computer are stored. For example, it may be a ROM (Read Only Memory), a RAM (Random Access Memory), a magnetic tape, a magnetic disk, a flash memory, an optical data storage device, or the like.

The embodiments disclosed with reference to the accompanying drawings have been described above. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. The disclosed embodiments are illustrative and should not be construed as limiting.

100: media device
110: audio signal receiver
120:
130:
131: Processor
132: Memory
210: decoder
220: First chip
221: first clock generating unit
222: second clock generating unit
223: Data modulation section
230: Second chip
231: first clock demodulator
232: second clock demodulator
233:
140:

Claims (20)

An audio signal receiving unit for receiving audio data from an audio source; And
And a chip for processing the audio data,
Wherein the one of the chips comprises: a clock generator for generating a clock signal and changing a pulse rate of the clock signal based on a format standard of the audio data; and a clock generator for modulating the audio data in accordance with a data transmission specification of the one chip And a data modulator for transmitting a data packet including the audio data in synchronization with the clock signal. The method according to claim 1,
Wherein the clock generator comprises:
A first clock generator for generating, as a first clock signal, an L signal indicating that data of the L channel is transmitted and an R signal indicating that the data of the R channel are transmitted so that the audio data of the stereo type is transmitted;
And a second clock generator for generating a second clock signal for the data modulation unit to synchronize. The method according to claim 1,
Wherein the clock generator increases the pulse rate when the format specification of the audio data is larger than the data transmission specification of the one of the chips. The method according to claim 1,
Wherein the clock generating unit doubles the pulse rate when the format specification of the audio data is larger than the data transmission specification of the one of the chips and is less than twice the data transmission specification. The method according to claim 1,
Wherein the data modulator allocates a part of the data packet as a parity area, transmits information on a format standard of the audio data in the parity area, and transmits the audio data in a remaining area of the data packet excluding the parity area Lt; / RTI > 6. The method of claim 5,
Wherein the data modulator allocates a part of the data packet as a parity area when the format specification of the audio data is larger than the data transmission specification of the one chip but less than twice the data transmission specification. 6. The method of claim 5,
Wherein the data modulator allocates a first end of the data packet as a parity area. 6. The method of claim 5,
Wherein the data modulator allocates a last end of the data packet as a parity area. The method according to claim 1,
Wherein the data modulator divides and transmits the data packet when the format specification of the audio data is larger than the data transmission specification of the one of the chips. The method according to claim 1,
Further comprising another chip for receiving a clock signal and a data packet having a changed pulse rate from any one of the chips,
Wherein the other chip reduces the pulse rate of the clock signal and reduces the audio data according to a format specification of the audio data. 11. The method of claim 10,
The other chip modulates the audio data into an analog audio signal,
Wherein the media device further comprises an acoustic unit for outputting sound based on the analog audio signal. Receiving audio data from an audio source;
Modifying the pulse rate of the clock signal based on the format specification of the audio data and modulating the audio data according to a data transmission specification of a certain chip; And
Transmitting the clock signal at a changed pulse rate, and transmitting a data packet including the audio data in synchronization with the clock signal. 13. The method of claim 12,
Wherein the transmitting the clock signal comprises:
Transmitting, as a first clock signal, an L signal indicating that the data of the L channel is transmitted and an R signal indicating that the data of the R channel are transmitted so that the audio data of the stereo type is transmitted;
And transmitting a second clock signal for synchronization of the step of transmitting the data packet. 13. The method of claim 12,
Wherein changing the pulse rate of the clock signal comprises increasing the pulse rate when the format specification of the audio data is greater than the data transmission specification of the one of the chips. 13. The method of claim 12,
The step of changing the pulse rate of the clock signal includes a step of doubling the pulse rate when the format specification of the audio data is larger than the data transmission specification of the one chip but less than twice the data transmission specification Of the media device. 13. The method of claim 12,
Wherein modulating the audio data comprises assigning a portion of the data packet as a parity area,
Wherein the step of transmitting the data packet includes transmitting information on a format standard of the audio data in the parity area and transmitting the audio data in a remaining area of the data packet excluding the parity area Control method. 17. The method of claim 16,
Wherein the step of allocating a part of the data packet as the parity area includes the step of, when the format specification of the audio data is larger than the data transmission specification of the one chip but less than twice the data transmission specification, The method comprising the steps of: 13. The method of claim 12,
Wherein the step of transmitting the data packet includes dividing and transmitting the data packet when the format specification of the audio data is larger than the data transmission specification of the one of the chips. 13. The method of claim 12,
Reducing the pulse rate of the clock signal and reducing the audio data according to a format specification of the audio data. 20. The method of claim 19,
Modulating the audio data into an analog audio signal; And
And outputting sound based on the analog audio signal.

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