JP3952568B2 - Digital audio signal transmission apparatus and digital audio signal transmission method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention provides a digital data rate that can be variably set.audioThe present invention relates to signal transmission technology.
[0002]
[Prior art]
In transmitting a digital signal, a method of transferring digital data including clock information and reproducing the clock information on the receiving side is known.
[0003]
FIG. 6 shows a main part of such a configuration example. In the device A on the transmission side, a transport unit b having a reference clock signal generation unit a (a crystal oscillator or the like), and a control unit for controlling the control unit b. c (microcomputer or the like), and an interface (I / F) part d for connection to an external device.
[0004]
The transport unit b includes a device that reproduces information from a recording medium in which an audio signal or the like is recorded as a digital signal and outputs the information to an external device, a digital data communication device, or the like.
[0005]
On the other hand, the device B on the receiving side is provided with an interface unit f that receives information from the interface unit d of the device A through a connection member e such as an optical cable or a coaxial cable. A (digital-analog converter) part g (for example, 1-bit DAC) is arranged, and a control unit h (microcomputer or the like) controls these controls.
[0006]
Thus, the reference clock signal generated by the reference clock signal generator a of the device A is sent from the transport unit b together with the digital data to the interface unit d, and from here to the interface unit f of the device B via the connection member e. Sent out. The interface section f separates the digital data and the clock signal and sends them to the DAC section g, where the clock signal is reproduced and D (digital) / A (analog) conversion is performed.
[0007]
By the way, since the clock signal used in the DAC unit g is a clock signal regenerated from the signal output from the interface unit f, the clock signal is not synchronized between the devices A and B, but is regenerated. If the clock signal includes a jitter (temporal fluctuation) component, there is a risk of causing signal deterioration of data after D / A conversion (for example, deterioration of sound quality or image quality).
[0008]
Therefore, in order to solve this inconvenience, as shown in FIG. 7, the transport part b ′ of the device A is not provided with the reference clock signal generator, and the reference clock signal is generated in the DAC part g ′ of the device B. A configuration in which the part i is provided and the synchronization signal Sy is sent from the DAC part g ′ to the device A can be mentioned.
[0009]
That is, in this case, since the DAC unit g ′ generates a stable clock signal with less jitter components, high-quality D / A conversion can be performed, so that signal degradation is reduced. In order to eliminate the synchronization error of the clock signal with B, it is necessary to send the synchronization signal Sy from the DAC part g ′ of the apparatus B to the transport part b ′ of the apparatus A through the connection member e ′.
[0010]
In addition, according to the IEEE (Institute of Electrical and Electronics Engineers) 1394 standard, which has begun to spread recently, there is a method of transmitting not only audio data but also various data (image signal, control signal, etc.) simultaneously with one cable. FIG. 8 shows a configuration proposed for transferring audio data in the standard.
[0011]
In this case, a method of synchronizing the clock signals by providing the device C as a master for generating a reference clock signal for communication to a plurality of devices is used. In the device C, the reference clock signal generator j and A bidirectional interface unit k is provided, and the bidirectional interface unit k is placed under the control of a control unit (such as a microcomputer) l.
[0012]
Further, the transport part b ′ and the bidirectional interface part d ′ provided in the transmission side apparatus A are placed under the control of the control part c, and the bidirectional interface part d ′ is connected to the apparatus by a connecting member (cable) m. It is connected to the bidirectional interface section k of C, and is also connected to the bidirectional interface section f ′ in the apparatus B by a connecting member (cable) n.
[0013]
In the device B, a bidirectional interface unit f ′ and a DAC unit g placed under the control of the control unit h are provided, and the clock signal and data separated by the bidirectional interface unit f ′ are provided in the DAC unit. The clock signal is reproduced and D / A converted. The bidirectional interface unit f ′ can be connected to an interface unit of a device other than the device A through a cable.
[0014]
[Problems to be solved by the invention]
However, the above-described configurations have the following problems.
[0015]
(1) The configuration shown in FIG. 7 requires a connection member e for sending data from the device A to the device B, and a connection member e ′ for sending a synchronization signal Sy from the device B to the device A. Therefore, a single transmission path cannot be integrated, and the connection relationship becomes complicated.
[0016]
(2) According to the configuration shown in FIG. 8, it is possible to share the reference clock signal in a plurality of devices, but D / A conversion can be performed with a clock signal having a large jitter component after resynchronization in the device B. If done, signal degradation may still be caused.
[0017]
Therefore, an object of the present invention is to transmit a digital signal without complicating a signal transmission path or causing signal deterioration.
[0018]
[Means for Solving the Problems]
  In order to solve the problems described above, the present inventionA first device having a first transmission / reception unit for transmitting / receiving a digital audio signal and a first control unit for variably controlling the transfer rate of the digital audio signal in the first transmission / reception unit; A second transmission / reception unit connected to the transmission / reception unit of the apparatus by a bidirectional communication member, a storage unit for storing the digital audio signal received by the second transmission / reception unit, and the digital audio signal from the storage unit A digital audio signal transmission device for transmitting the digital audio signal to and from a second device comprising a conversion unit for reading and converting to an analog audio signal and a second control unit for controlling each of these units; A method for generating a first reference clock signal for performing communication between the first transmitting / receiving unit and the second transmitting / receiving unit. A reference clock generation unit; and a second reference clock generation unit for generating a second reference clock signal for converting the digital audio signal into an analog audio signal for the conversion unit. The second control unit of the apparatus monitors the data amount of the digital audio signal stored in the storage unit, and the transfer rate of the first reference clock signal is the conversion rate of the second reference clock signal. Higher, if the amount of data stored in the storage unit is greater than a predetermined reference value, the transfer rate of the first reference clock signal is lower than the conversion rate of the second reference clock signal; The transfer rate of the first reference clock signal is lower than the conversion rate of the second reference clock signal, and the amount of data stored in the storage unit is a predetermined reference The first reference clock signal is variably controlled by the first control unit so that the transfer rate of the first reference clock signal is higher than the conversion rate of the second reference clock signal. It is characterized by that.
[0019]
  Therefore, according to the present invention, data transmission / reception between the first device and the second device can be performed by connecting the transmission / reception unit of each device with a bidirectional communication member. A reference clock signal generator for generating a stable reference clock signal is provided for the converter in the device 2In addition to the first reference clock generation unit that generates the first reference clock signal for performing communication between the first transmission / reception unit and the second transmission / reception unit, the digital audio signal is supplied to the conversion unit. At least a second reference clock generation unit for generating a second reference clock signal for converting the analog audio signal into an analog audio signal, and the control unit (second control unit) of the second device stores in the second device The data amount of the digital audio signal stored in the storage unit is monitored, and the transfer rate of the first reference clock signal is higher than the conversion rate of the second reference clock signal and stored in the storage unit. When the amount of data is larger than a predetermined reference value, the transfer rate of the first reference clock signal is made lower than the conversion rate of the second reference clock signal, and the first reference clock signal When the transmission speed is lower than the conversion speed of the second reference clock signal and the amount of data stored in the storage unit is smaller than a predetermined reference value, the transfer speed of the first reference clock signal is Variable control is performed by the first control unit so as to be higher than the conversion speed of the second reference clock signal.As a result, it is possible to prevent signal degradation by eliminating the influence of temporal fluctuations associated with signal transmission.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
  FIG. 1 shows the digital of the present invention.audio1 shows a basic configuration of a signal transmission device 1 and includes a first device A and a second device B.
[0021]
The first device A includes a transmission / reception unit 2 for transmitting / receiving digital signals, and a control unit 3 for variably controlling the data transfer rate in the transmission / reception unit 2. The transmission / reception unit 2 includes a transport unit that reproduces and outputs data from a recording medium on which a digital signal is recorded, such as a CD (compact disc), a DVD (digital video disc), or a DAT (digital audio tape). Alternatively, a communication unit that transmits and receives digital signals, means necessary for an interface for communication with the second apparatus B, and the like are included.
[0022]
In addition, the second device B is used to temporarily store the transmission / reception unit 5 connected to the transmission / reception unit 2 of the first device A by the bidirectional communication member 4 and the data received by the transmission / reception unit 5. A storage unit 6; a conversion unit 7 for reading out data from the storage unit 6 and performing signal conversion (for example, D / A conversion, signal format conversion, etc.); and a control unit 8 for controlling these units. have.
[0023]
A reference clock signal generation unit 9 for generating a reference clock signal is provided in the second device B for the conversion unit 7, and an output signal converted by the conversion unit 7 is output from the second device B. Output.
[0024]
The control unit 8 of the second device B monitors the usage status of the storage unit 6 and sends a signal to the control unit 3 of the first device A via the bidirectional communication member 4, thereby The data transfer rate from the transmission / reception unit 2 to the transmission / reception unit 5 of the apparatus B is variably controlled.
[0025]
Examples of monitoring items regarding the usage status of the storage unit 6 include the remaining amount of data and the remaining amount of memory as shown below.
[0026]
(I) Remaining data = amount of data stored in the storage unit
(Ii) Remaining memory = the amount obtained by subtracting the amount of data stored in the storage unit from the storage capacity of the storage unit, that is, the free capacity.
[0027]
When the usage status of the storage unit 6 is monitored based on the remaining amount of data (i) above, the control unit 3 of the first device A from the control unit 8 of the second device B via the bidirectional communication member 4. When the remaining amount of data is larger than the reference value by sending a signal to the device, the data transfer rate from the transmission / reception unit 2 of the device A to the transmission / reception unit 5 of the device B is reduced, and the remaining amount of data is less than the reference value In this case, control is performed so as to increase the data transfer rate from the transmission / reception unit 2 of the device A to the transmission / reception unit 5 of the device B.
[0028]
FIG. 2 conceptually shows the relationship between the remaining amount of data and the remaining amount of memory on the horizontal axis and the data transfer speed on the vertical axis. For example, the remaining amount of data in the storage unit 6 is within an allowable range. (Indicated by “ΔW” in the figure) When the data transfer rate is “1”, if the remaining data amount is large, the transfer rate is set to α (0 <α according to the remaining data amount). <1) The speed is reduced to twice the speed, and if the remaining amount of data is small, the transfer speed is set to β (> 1) times according to the remaining data amount.
[0029]
Further, the present invention is not limited to this, and various modes such as adopting a setting in which the data transfer rate gradually decreases as the remaining amount of data increases as shown by the broken line G1 and the two-dot chain line G2 in FIG. Is possible.
[0030]
  When the usage status of the storage unit 6 is monitored based on the remaining amount of memory in (ii) above (ideally, with respect to the amount of data in the storage unit, it is ideal to store as much data as possible in the storage unit so that the storage unit does not overflow) For this purpose, it is fundamental to know the remaining memory capacity.) The second deviceBWhen the remaining memory is less than the reference value by sending a signal from the controller 8 to the controller 3 of the first device A via the bidirectional communication member 4, the transmitter / receiver 2 of the device A When the data transfer rate to the transmission / reception unit 5 of the device B is reduced and the remaining memory capacity is larger than the reference value, the data transfer rate from the transmission / reception unit 2 of the device A to the transmission / reception unit 5 of the device B is increased. Take control.
[0031]
For example, as shown in FIG. 2, when the data transfer speed when the remaining memory capacity is within the allowable range ΔW is “1”, the transfer speed is set according to the remaining memory capacity when the remaining memory capacity is low. Is reduced to α (0 <α <1) times, and if the remaining memory is large, the transfer speed is set to β (> 1) times according to the remaining amount of data, or It is possible to adopt a setting in which the data transfer rate continuously increases as the remaining amount of memory increases, as shown by the line segment G1 and the curve G2.
[0032]
The device C shown in FIG. 1 is a device having means (communication reference clock signal generation unit) 10 for generating a communication reference clock signal as in the case of adopting the above-mentioned IEEE 1394 standard. Is sent to the transmission / reception unit 2 of the first device A via the communication member 4 '. The transmission / reception unit 2 of the first device A sends information including the communication reference clock signal to the transmission / reception unit 5 of the second device B. The reference clock signal used by the conversion unit 7 is the above-described reference. Since this is a stable clock signal (having almost no jitter component) obtained by the clock signal generator 9, there is no reduction in signal deterioration during signal conversion.
[0033]
Further, the right to determine the data transfer rate can be given to the control unit of the device A or the device B. For example, when the decision right is given to the control unit 3 of the device A, the control unit 8 of the device B only reports to the control unit 3 of the device A only the report on the usage status of the storage unit 6 and sends the report. The control unit 3 of the received device A determines the data transfer rate. In addition, when the right to determine is given to the control unit 8 of the device B, the control unit 8 grasps the usage status of the storage unit 6 and sends an instruction of the data transfer speed according to this to the control unit 3 of the device A. Send out to determine the data transfer rate.
[0034]
【Example】
FIGS. 3 to 5 show an embodiment of the present invention. An apparatus having a transport unit for reproducing digital audio media and its reproduction data are temporarily stored in a memory and then D / A converted by a DAC unit to be analog. In the sound reproducing device 11 having a device for outputting a signal, a configuration example is shown in which the memory usage status is monitored and the data transfer rate is variably controlled by computer communication between the transport unit and the DAC unit. It is.
[0035]
In FIG. 3, a transport unit 12 and a bidirectional interface unit 13 are provided in the device A, and these are placed under the control of the microcomputer 14. The transport unit 12 reproduces data from a digital audio medium (not shown) and then sends the data to the device B via the bidirectional interface unit 13. The transport unit 12 and the bidirectional interface unit 13 correspond to the transmission / reception unit 2 described above, the microcomputer 14 corresponds to the control unit 3 described above, and the transport unit 12 receives the instruction signal St from the microcomputer 14. In response, the data reproduction speed is variably controlled.
[0036]
The device B is provided with a bidirectional interface unit 15, and is connected to the bidirectional interface unit 13 of the device A via a communication cable 16. A memory 17 having a predetermined storage capacity is provided after the bidirectional interface unit 15, and data read from the memory 17 is sent to the DAC unit 18.
[0037]
The bidirectional interface unit 15 corresponds to the transmission / reception unit 5, the memory 17 corresponds to the storage unit 6, and the DAC unit 18 corresponds to the conversion unit 7. (Corresponding to section 8)).
[0038]
Further, the microcomputer 19 constantly monitors the remaining amount of data in the memory 17 (see the signal Sm from the memory 17 to the microcomputer 19 in FIG. 3), and the data transfer rate corresponding to the remaining amount of data is set in the device A. The microcomputer 14 is instructed.
[0039]
The DAC unit 18 is provided with a reference clock signal generation unit 20 for generating a stable reference clock signal (hereinafter referred to as “Sck”), which corresponds to the reference clock signal generation unit 9 described above. To do.
[0040]
The device C is a master device that generates communication reference clock signals for a plurality of devices, and includes a reference clock signal generation unit 21 and a bidirectional interface unit 22, and the bidirectional interface unit 22 is a microcomputer 23. Is under control. The bidirectional interface unit 22 is connected to the bidirectional interface unit 13 of the apparatus A via the communication cable 24.
[0041]
FIG. 4 is a flowchart showing an example of the control. First, after the microcomputer 19 of the device B measures the amount of data in the memory 17 in step S1, the remaining amount of data is grasped, and then in the next step S2, the device B The microcomputer 19 determines whether the remaining data amount is within a reference range (for example, 80 to 90% of the memory capacity).
[0042]
That is, if the remaining data amount is within the reference range, the process proceeds to step S3. If the remaining data amount is not within the reference range, the remaining data amount is less than the lower limit value of the reference range and the remaining data amount is within the reference range. In the former case, the process proceeds to step S6, and in the latter case, the process proceeds to step S9.
[0043]
In step S3, the microcomputer 19 of the apparatus B instructs the microcomputer 14 of the apparatus A to set the data transfer speed to be one time the reference speed, and then in the next step S4, the microcomputer 14 of the apparatus A. In response to an instruction from the microcomputer 19 of the apparatus B, the reproduction speed of the transport unit 12 is adjusted to the reference speed, and the transfer rate is set as the reference value. Thereby, in step S5, the data transfer rate is set to one time the reference rate.
[0044]
In step S6, the microcomputer 19 of the apparatus B instructs the microcomputer 14 of the apparatus A to set the data transfer speed to 1.2 times the reference speed, and in the next step S7, the apparatus A In response to an instruction from the microcomputer 19 of the apparatus B, the microcomputer 14 adjusts the reproduction speed of the transport unit 12 and changes the transfer rate accordingly. Thus, in step S8, the data transfer rate is set to 1.2 times the reference rate.
[0045]
On the other hand, in step S9, the microcomputer 19 of the apparatus B instructs the microcomputer 14 of the apparatus A to set the data transfer rate to 0.8 times the reference speed, and then in the next step S10, the apparatus A In response to an instruction from the microcomputer 19 of the apparatus B, the microcomputer 14 adjusts the reproduction speed of the transport unit 12 and changes the transfer rate accordingly. Thus, in step S11, the data transfer speed is set to 0.8 times the reference speed.
[0046]
The digital data whose data transfer rate is controlled as described above is temporarily stored in the memory 17 from the bidirectional interface unit 13 of the device A through the bidirectional interface unit 15 of the device B, and then sequentially read out. The DAC unit 18 performs D / A conversion to an analog signal. Then, returning from step S5, S8, S11 to step S1 again, monitoring of the remaining memory and control of the data transfer rate are repeated until the end of data transfer.
[0047]
The DAC unit 18 of the device B can perform D / A conversion of the data in the memory 17 according to the reference clock signal Sck of the reference clock signal generation unit 20 attached to the DAC unit regardless of the communication reference clock from the device C. Therefore, an analog audio signal with good sound quality can be obtained by using a clock signal with very little jitter component.
[0048]
The operation of each device after the start of the digital audio media playback operation in the device A will be briefly described. First, since data is hardly stored in the memory 17 of the device B immediately after the start of playback. The microcomputer 19 of the apparatus B issues an instruction to the microcomputer 14 of the apparatus A to set the data transfer speed to 1.2 times the reference speed (see step S6 in FIG. 4). As a result, the device A plays back the digital audio media at a playback speed 1.2 times the reference speed value, and the device B reads out from the memory 17 according to the reference clock signal Sck of the DAC unit 18 and converts it into an analog signal. .
[0049]
Data is sent from the device A at a transfer rate of 1.2 times the reference speed and is gradually stored in the memory 17 of the device B, and the remaining amount of data increases with time. When the amount of data in the memory 17 reaches the lower limit of the reference range, for example, a value corresponding to about 80% of the memory capacity, data transfer from the microcomputer 19 of the device B to the microcomputer 14 of the device A is performed. An instruction is issued to make the speed one time the reference speed (see step S3 in FIG. 4). In accordance with this instruction, the microcomputer 14 of the device A changes the playback speed and transfer rate of the digital audio media to a value that is one time the reference value.
[0050]
Since a finite time is required for the reproduction speed and the like to be changed to the reference value, the data amount in the memory 17 also increases during this period, for example, this becomes 80% of the memory capacity.
[0051]
This amount of data is constant without changing when the clock signal at the time of transmission of the device A and the reference clock signal Sck of the DAC unit 18 are synchronized. This is because the reproduction speed and transfer rate are set as reference values, and the data in the memory 17 is D / A converted with a reference clock signal Sck having a rate (frequency) equal to or higher than the reference value, and the data remaining The amount will not increase any further.
[0052]
However, if such synchronization is not achieved, the remaining amount of data fluctuates without maintaining a constant equilibrium value.
[0053]
For example, when the transmission system including the transport unit 12 of the device A sends data to the device B at a speed faster than the operation of the DAC unit 18, even after the remaining amount of data reaches the lower limit value of the reference range. It increases little by little. When the remaining data amount exceeds the upper limit value of the reference range, for example, a value corresponding to 90% of the memory capacity, the data transfer speed is set to the reference speed from the microcomputer 19 of the apparatus B to the microcomputer 14 of the apparatus A. An instruction is issued to increase the value by 0.8 and the data transfer rate is changed (see steps S9 to S11 in FIG. 4). Thereafter, the data transfer speed becomes 0.8 times the reference speed until the remaining data amount becomes equal to or less than the upper limit value of the reference range. When the remaining data amount is less than or equal to the upper limit value of the reference range, the data transfer speed is changed to become the reference speed (1 time again), and the remaining data amount changes around the upper limit value of the reference range. The data transfer speed is variably controlled according to the above.
[0054]
On the other hand, when the transmission system including the transport unit 12 of the device A sends data to the device B at a speed slower than the operation of the DAC unit 18, the remaining data amount slightly exceeds the lower limit value of the reference range. It gradually decreases from the amount (for example, 80% of the memory capacity), and eventually falls below the lower limit of the reference range. At that time, the microcomputer 19 of the apparatus B instructs the microcomputer 14 of the apparatus A to set the data transfer speed to 1.2 times the reference speed, and the data transfer speed is changed (FIG. 4). (See steps S6 to S8.) Thereafter, the data transfer rate becomes 1.2 times the reference rate until the remaining data amount becomes equal to or higher than the lower limit value of the reference range. When the remaining data amount exceeds the lower limit value of the reference range, the data transfer rate is changed to become the reference speed (1 time again), and the remaining data amount changes around the lower limit value of the reference range. The data transfer speed is variably controlled according to the above.
[0055]
In the above description, the reference range is set for the remaining data amount as shown in step S2 of FIG. 4 and divided into three ranges for determining the remaining data amount. The reference range for the remaining amount of data is not limited to 80% to 90% of the memory capacity, and the range is appropriately determined according to the transmission speed and the conversion speed of the DAC unit. Of course, it can be set to.
[0056]
In the above example, the right to determine the data transfer speed is in the microcomputer 19 of the apparatus B, and the microcomputer 19 judges the use status of the memory 17 and sends the data transfer speed to the microcomputer 14 of the apparatus A. However, the microcomputer 19 of the device B sends only information relating to the usage state (data remaining amount or memory remaining amount) of the memory 17 to the microcomputer 14 of the device A, and the device is based on the information. The microcomputer A can determine the data transfer rate and issue an instruction to the transport unit 12. In this case, for example, the processing shown in the flowchart of FIG. 5 is performed. .
[0057]
That is, after the microcomputer 19 of the device B measures the amount of data in the memory 17 in step S1 to grasp the remaining amount of data or the remaining amount of memory, in the next step S2, information on the remaining amount of data or the remaining amount of memory is obtained. The microcomputer 19 of the device B notifies the microcomputer 14 of the device A.
[0058]
In the next step S3, the microcomputer 14 of the device A determines whether or not the remaining amount of data is within a reference range (for example, 80 to 90% of the memory capacity).
[0059]
That is, if the remaining data amount is within the reference range, the process proceeds to step S4. If the remaining data amount is not within the reference range, the remaining data amount is less than the lower limit value of the reference range and the remaining data amount is within the reference range. In the former case, the process proceeds to step S6, and in the latter case, the process proceeds to step S8.
[0060]
In step S4, the microcomputer 14 of the device A adjusts the reproduction speed of the transport unit 12 to the reference speed and sets the transfer rate as a reference value. Thereby, in step S5, the data transfer rate is set to one time the reference rate, and then the process returns to step S1.
[0061]
In step S6, the microcomputer 14 of the device A adjusts the reproduction speed of the transport unit 12 and changes the transfer rate according to the adjustment. In step S7, the data transfer speed is changed to 1.2 of the reference speed. After setting to double, the process returns to step S1.
[0062]
In step S8, the microcomputer 14 of the apparatus A adjusts the reproduction speed of the transport unit 12 of the apparatus B and changes the transfer rate according to this, and in step S9, the data transfer speed is set to the reference speed 0. After setting to 8 times, the process returns to step S1.
[0063]
It should be noted that by increasing the storage capacity of the memory 17 described above, it is possible to prevent sound skipping, that is, to use for ESP (Electronic Shock Protection) processing. Here, the “ESP process” is a process for preventing a sound skip caused by a disturbance by using a storage means called a sound skip guard memory (or Shock Resistant Memory) as a buffer and improving vibration resistance. is there.
[0064]
Even if the transmission data of the transport unit 12 of the device A is temporarily interrupted due to external impact or vibration, a certain amount of data is accumulated in the memory 17 of the device B, so that the data is read out. If the reproduction in the transport unit 12 is restored before the time is lost, the audio data can be reproduced without interruption.
[0065]
【The invention's effect】
  As is clear from the above description, claim 1And claim 4According to the invention which concerns on, between 1st apparatus and 2nd apparatus,Digital signalSince the transmission / reception of each device can be performed by connecting the transmission / reception unit of each device with a member for bidirectional communication, the connection relationship of communication is not complicated. Further, by adding a reference clock signal generation unit for generating a stable reference clock signal to the conversion unit in the second device, it is possible to eliminate the influence of temporal fluctuations associated with signal transmission and prevent signal deterioration, and jitter. A signal with very few components can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a basic configuration of the present invention.
FIG. 2 is a graph for explaining the relationship between the remaining amount of data or the remaining amount of memory and the data transfer speed.
3 is a diagram for explaining an embodiment of the present invention together with FIG. 4, and this diagram is a circuit block diagram showing a configuration. FIG.
FIG. 4 is a flowchart showing an example of control.
FIG. 5 is a flowchart showing an example of control when the right to determine the data transfer rate is given to the microcomputer of the device A.
FIG. 6 is a circuit block diagram showing a conventional configuration example.
FIG. 7 is a circuit block diagram showing an example of a conventional configuration for achieving high sound quality.
FIG. 8 is a circuit block diagram showing a conventional configuration example provided with a communication interface between microcomputers.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Digital signal transmission apparatus, A ... 1st apparatus, B ... 2nd apparatus, 2, 5 ... Transmission / reception part, 3, 8 ... Control part, 4 ... Member for two-way communication, 6 ... Memory | storage part, 7 ... Conversion unit, 9... Reference clock signal generation unit

Claims (2)

First and apparatus having a first control unit for variably controlling the transfer rate of the digital audio signal in the first transceiver and said first transceiver for transmitting and receiving digital audio signal,
The second transceiver, a storage unit for the second transceiver stores the digital audio signal received connected by the transmission and reception unit and the two-way communication member of the first device, the from the storage unit and a second device having a second control unit that controls the converting unit and control of these units for converting an analog audio signal by reading the digital audio signal,
Have
A digital audio signal transmission apparatus for transmitting the digital audio signal between the first apparatus and the second apparatus,
A first reference clock generator for generating a first reference clock signal for performing communication between the first transmitter / receiver and the second transmitter / receiver;
A second reference clock generator for generating a second reference clock signal for converting the digital audio signal into an analog audio signal for the converter ;
Comprising at least
Monitors the data amount of the digital audio signal from which the second control unit of the second device is stored in the storage unit, the first reference clock signal reference clock transfer speed the second of When the signal conversion rate is higher than the signal conversion rate and the amount of data stored in the storage unit is larger than a predetermined reference value, the transfer rate of the first reference clock signal is higher than the conversion rate of the second reference clock signal. If the transfer rate of the first reference clock signal is lower than the conversion rate of the second reference clock signal and the amount of data stored in the storage unit is smaller than a predetermined reference value, The digital control unit is variably controlled by the first control unit so that a transfer rate of the first reference clock signal is higher than a conversion rate of the second reference clock signal. Tal audio signal transmission device. First and apparatus having a first control unit for variably controlling the transfer rate of the digital audio signal in the first transceiver and said first transceiver for transmitting and receiving digital audio signal, the first A second transmission / reception unit connected to the transmission / reception unit of the apparatus by a bidirectional communication member, a storage unit for storing the digital audio signal received by the second transmission / reception unit, and the digital audio signal from the storage unit in digital audio signal transmission method for transmitting the digital audio signal with the second device comprising a second control unit that controls the converting unit and control of these units for converting an analog audio signal by reading There,
A first reference clock generator for generating a first reference clock signal for performing communication between the first transmitter / receiver and the second transmitter / receiver;
A second reference clock generator for generating a second reference clock signal for converting the digital audio signal into an analog audio signal for the converter ;
At least,
Monitors the data amount of the digital audio signal from which the second control unit of the second device is stored in the storage unit, the first reference clock signal reference clock transfer speed the second of When the signal conversion rate is higher than the signal conversion rate and the amount of data stored in the storage unit is larger than a predetermined reference value, the transfer rate of the first reference clock signal is higher than the conversion rate of the second reference clock signal. If the transfer rate of the first reference clock signal is lower than the conversion rate of the second reference clock signal and the amount of data stored in the storage unit is smaller than a predetermined reference value, The digital audio is variably controlled by the first control unit so that a transfer rate of the first reference clock signal is higher than a conversion rate of the second reference clock signal. Io signal transmission method.

Images