JP2012124824A - Data transmission device and data transfer device and data transfer method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable serial data to be transferred at a frequency suitable for a data receiving device without causing bit dropouts.SOLUTION: To a data receiving device which, upon receiving a data transfer cycle signal 5 indicating one interval of transfer repeatedly, generates a strobe pulse repeatedly from the data transfer cycle signal 5 and receives data successively by the strobe pulse, does a data transmitting device 1 transmit a data transfer cycle signal 5 synchronously with a transmit clock and further transmit data successively in synchronism with the data transfer cycle signal 5. The data transmitting device 1 determines, by a control unit 2, a data transfer cycle width 4 based on information about a receive clock frequency of the data receiving device so that the predetermined number or a greater number of receive clock periods will be inserted within a data transfer cycle indicating one interval of data transfer, and transmits, by a transmission unit 3, one data in one interval of data transfer having the data transfer cycle width 4 determined by the control unit 2.

Description

  The present invention relates to a data transmission device, a data transfer device, and a data transfer method, and more particularly to a data transmission device, a data transfer device, and a data transfer method that transmit and receive data based on a clock.

  The data transfer device has a data transmission device and a data reception device, the data transmission device transmits data based on the transmission clock, and the data reception device receives data transmitted by the data transmission device based on the reception clock. ing.

  FIG. 4 shows an example of a time chart relating to serial transfer of data by the data transfer device.

  As shown in FIG. 4, the data transmission device 15 generates a strobe signal (STB signal: data transfer cycle signal) synchronized with the transmission clock (Snd-CLK), and the STB signal cycle interval (that is, data transfer). 1-bit data is transmitted with a cycle width (for example, 4 CLK width). Then, serial data is transmitted by continuously transmitting 1-bit data in synchronization with the STB signal.

  The data receiving device 16 generates a reception clock (Rcv-CLK) having a frequency such that, for example, 8 CLKs are included in one cycle of the STB signal, and receives the STB signal in synchronization with the reception clock. The data receiver 16 includes, for example, three synchronization flip-flops (F / F). When the STB signal received in synchronization with the reception clock is “high”, the first F / F is used as the STBF 0. Raise the signal. Then, the STBF1 signal is raised at the second F / F in synchronization with the next reception clock, and the STBF2 signal is raised at the third F / F in synchronization with the next reception clock. Subsequently, when the STB signal received in synchronization with the reception clock is “low”, the STBF0 signal is lowered at the first F / F. Then, the STBF1 signal falls at the second F / F in synchronization with the next reception clock, and the STBF2 signal falls at the third F / F in synchronization with the next reception clock.

  In this manner, the STB signal delayed by one cycle of the reception clock is reproduced by the three F / Fs. Then, a strobe pulse (STBpulse) is repeatedly generated in the interval between the rising edge of the reproduced second STB signal (STBF1 signal) and the rising edge of the third STB signal (STBF2 signal). Serial data is received by repeatedly acquiring 1-bit data transmitted by the data transmitter 15 using the strobe pulse as a strobe signal.

  As described above, the data receiving device 16 reproduces the STB signal in synchronization with the reception clock, and receives serial data using the strobe pulse generated based on the reproduced STB signal as the strobe signal.

  For this reason, when the frequency of the reception clock of the data receiving device 16 is slow, a deviation occurs between the strobe pulse generated by the reproduced STB signal and the timing of the 1-bit data to be received by the STB signal transmitted by the data transmitting device 15. there's a possibility that. For example, as shown in FIG. 5 (an example of a case where the reception clock is delayed in the time chart shown in FIG. 4), reception within the data transfer cycle width of the strobe signal (STB signal) transmitted by the data transmission device 15 is performed. When the number of clocks is small (two in the case of FIG. 5), 1-bit data corresponding to the STB signal transmitted by the data transmission device 15 cannot be normally received. In this case, bit0 that should be received by the first strobe pulse is not received, and bit1 is received. That is, bit 0 of serial data cannot be received. For this reason, there is a problem in that bit missing occurs in the serial data to be received, and normal data transfer cannot be performed.

  A technique for solving such a problem is described in Patent Document 1. As shown in FIG. 6, the serial data communication system described in Patent Document 1 includes a data transmission unit 17 that transmits transmission data, and a data reception unit 18 that receives transmission data transmitted by the data transmission unit 17 based on a reception clock. And have.

  The data receiving unit 18 generates a synchronous clock having a cycle obtained by multiplying the cycle of the reception clock, and transmits the generated synchronous clock to the data transmitting unit 17. Further, a phase determination signal for determining whether or not the phase of the received transmission data and the reception clock is synchronized is generated, and the generated phase determination signal is transmitted to the data transmission unit 17. On the other hand, the data transmission unit 17 receives the synchronization clock and the phase determination signal from the data reception unit 18. Then, the data transmission unit 17 generates a high-frequency clock sufficiently faster than the frequency of the reception clock, and uses the synchronization clock and the phase determination signal received from the data reception unit 18 to perform transmission synchronized in frequency and phase with the reception clock. Data is generated based on the high frequency clock, and the generated transmission data is transmitted to the data receiving unit 18.

  For this reason, since the transmission data is frequency-synchronized and phase-synchronized with the reception clock, the data reception unit 18 receives the transmission data in synchronization. For this reason, bit loss is not generated in the received serial data, and normal data transfer can be performed.

  However, in order to solve the above-described problem, the serial data communication system described in Patent Document 1 has a circuit for generating a synchronous clock in the data receiving unit 18 and whether or not the phases of transmission data and reception clock are synchronized. A phase determination circuit for determining and outputting a phase determination signal is required. Further, the data transmission unit 17 requires a circuit that generates transmission data that is frequency-synchronized and phase-synchronized with the reception clock using the synchronization clock and the phase determination signal. For this reason, the serial data communication system described in Patent Document 1 has a problem that the configuration is complicated and expensive.

JP 2008-99228 A

  The serial data communication system described in Patent Document 1 described above requires various circuits and the like in the data transmission unit and the data reception unit so that normal data transfer can be performed without bit loss in the serial data. . For this reason, the serial data communication system described in Patent Document 1 has a problem that the configuration is complicated and expensive.

  An object of the present invention is to provide a data transmission device, a data transfer device, and a data transfer method that solve the above-described problems.

The first data transmission apparatus of the present invention receives a data transfer cycle signal indicating a section of transfer for transferring data continuously based on the reception clock, and repeats a strobe pulse from the data transfer cycle signal. The data transfer cycle signal is transmitted in synchronization with a transmission clock to a data receiving device that continuously generates the data using the strobe pulse, and the data transfer cycle signal is synchronized with the data transfer cycle signal. In a data transmission device that continuously transmits data,
The data transmission device includes:
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A control unit for determining the width of
A transmission unit that transmits one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the control unit.

According to the data transfer method of the present invention, the number of clocks of the reception clock equal to or greater than a predetermined number in a data transfer cycle indicating one section in which data is transferred by the data transmission device based on the frequency information of the reception clock of the data reception device. Determine the width of the data transfer cycle so that
Data that repeatedly indicates one section of transfer in which data is transmitted continuously while transmitting one data within the one section of the data transfer having the determined data transfer cycle width by the data transmitting device. In synchronization with a transfer cycle signal, the data is continuously transmitted to the data receiving device,
The data receiving device receives a data transfer cycle signal from the data transmitting device on the basis of the reception clock, repeatedly generates a strobe pulse for each cycle of the data transfer cycle signal, and uses the strobe pulse to continuously output the data. The data is received from the data transmission device.

The second data transmission apparatus of the present invention receives a data transfer cycle signal indicating a section of transfer for transferring data continuously based on the reception clock, and repeats a strobe pulse from the data transfer cycle signal. The data transfer cycle signal is transmitted in synchronization with a transmission clock to a data receiving device that is generated and continuously receives the data using the strobe pulse, and the data is synchronized with the data transfer cycle signal. In a data transmission device that continuously transmits
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A host device that determines the width of the
And a data transmission device having a transmission unit for transmitting one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the host device.

  According to the present invention, serial data can be transferred at a frequency suitable for the data receiving apparatus with no simple bits and without bit missing.

It is a figure which shows an example of the data transmitter which concerns on the 1st Embodiment of this invention. It is a figure which shows an example of the data transfer apparatus which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows an example of the operation | movement of the 2nd Embodiment of this invention. It is a figure which shows an example of the time chart regarding the serial transfer of the data by the data transfer apparatus in related technology. FIG. 5 is a diagram illustrating an example when the reception clock is delayed in the time chart illustrated in FIG. 4. It is a figure which shows an example of the serial data communication system in related technology.

Next, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a diagram illustrating an example of a data transmission apparatus according to the first embodiment of the present invention.

  The data transmission device 1 according to the present embodiment transmits data based on the transmission clock to the data reception device that receives data based on the reception clock. The data transmission device 1 includes a control unit 2 and a transmission unit 3.

  The data receiving apparatus is, for example, a data receiving apparatus that receives data according to the time charts shown in FIGS. 4 and 5 described in the background art section. That is, the data receiving apparatus receives from the data transmitting apparatus 1 the data transfer cycle signal 5 (STB signal in FIG. 4) in which the cycle of transferring data is continuously indicated based on the received clock. In this device, a strobe pulse is repeatedly generated every cycle, and data is continuously received from the data transmission device 1 by the strobe pulse.

  The control unit 2 of the data transmission device 1 receives a predetermined number (for example, eight) or more reception clocks in a data transfer cycle indicating one section for transferring data based on the frequency information of the reception clock of the data reception device. The width 4 of the data transfer cycle is determined so that the number of clocks is included. This predetermined number is a number by which the data receiving device that receives the data in the time chart shown in FIG. 4 can receive the serial data without causing bit loss. This predetermined number may be appropriately determined by the system.

  The transmission unit 3 of the data transmission device 1 transmits one data within one section of data transfer having the data transfer cycle width 4 determined by the control unit 2. At this time, the transmitter 3 transmits a data transfer cycle signal 5 (STB signal in FIG. 4) indicating a cycle signal for transferring data in synchronization with the transmission clock, and in synchronization with the data transfer cycle signal 5. Send data continuously. The data transfer cycle signal 5 is a signal that repeatedly indicates one section (one cycle) of data transfer when transferring data continuously.

  As described above, according to the first embodiment of the present invention, the control unit 2 uses a predetermined number (for example, 8) of reception clocks within a data transfer cycle indicating one section for transferring data. The width of the data transfer cycle is determined so that the number of clocks is included. Then, the transmission unit 3 transmits one data within one section of the data transfer having the data transfer cycle width 4 determined by the control unit 2. The transmission unit 3 transmits the data transfer cycle signal 5 in synchronization with the transmission clock, and continuously transmits data in synchronization with this signal. At this time, the data reception device receives the data transfer cycle signal 5 from the data transmission device 1 based on the reception clock, repeatedly generates a strobe pulse for each cycle of this signal, and continuously receives data by this strobe pulse. To do. Therefore, according to the embodiment of the present invention, the width of the data transfer cycle is determined so that a predetermined number (for example, 8) of reception clocks is included in the data transfer cycle, and the data reception cycle Send data to the device.

As described above, according to the first embodiment of the present invention, serial data can be transmitted without causing bit missing in the data receiving apparatus with the simple configuration as described above. Then, the serial data can be transmitted with the reception clock of the data reception device, that is, with the frequency suitable for the data reception device.
(Second Embodiment)
FIG. 2 is a diagram illustrating an example of a data transfer apparatus according to the second embodiment of the present invention.

  The data transfer device 6 according to the present embodiment includes a data transmission device 7 and a data reception device 8.

  The data transmission device 7 transmits data based on the transmission clock. The data receiving device 8 receives the data transmitted by the data transmitting device 7 based on the reception clock.

  The data receiving device 8 is, for example, the data receiving device 8 that receives data according to the time charts shown in FIGS. 4 and 5 described in the background art section. That is, the data receiving device 8 receives the data transfer cycle signal 5 (STB signal in FIG. 2) from the data transmitting device 7 based on the received clock, and repeatedly generates a strobe pulse for each cycle of the received signal. This is a device that continuously receives data from the data transmission device 7 using a strobe pulse.

  The data transmission device 7 includes a control unit 9 and a transmission unit 10.

  The transmission unit 10 includes a reception clock frequency detection unit 13, a data transfer cycle width setting unit 12, and a data transmission unit 11.

  The reception clock frequency detection unit 13 of the transmission unit 10 detects the frequency information of the reception clock from the data reception device 8 and outputs it to the control unit 9.

  The control unit 9 receives the frequency information of the reception clock from the reception clock frequency detection unit 13, and is a predetermined number (for example, 8) or more in a data transfer cycle indicating one section in which data is transferred based on this frequency information. The width of the data transfer cycle is determined so that the number of received clocks is included. The control unit 9 may acquire the frequency information of the reception clock by an operation from the outside of the data transmission device 7 and determine the data transfer cycle width 4 based on the acquired frequency information.

  The data transfer cycle width setting unit 12 of the transmission unit 10 sets the data transfer cycle width 4 determined by the control unit 9 in the data transmission unit 11.

  The data transmission unit 11 of the transmission unit 10 transmits 1-bit data within one section of data transfer having the data transfer cycle width 4 set by the data transfer cycle width setting unit 12. At this time, the data transmission unit 11 transmits the data transfer cycle signal 5 to the data reception device 8 in synchronization with the transmission clock, and continuously transmits the data to the data reception device 8 in synchronization with the data transfer cycle signal 5. Send.

  FIG. 3 is a flowchart showing an example of the operation of the data transfer apparatus according to this embodiment.

  In step S <b> 1 of FIG. 3, the reception clock frequency detection unit 13 of the transmission unit 10 detects the frequency information of the reception clock from the data reception device 8 and outputs it to the control unit 9.

  In step S2 of FIG. 3, the control unit 9 receives frequency information from the reception clock frequency detection unit 13, and based on this frequency information, a predetermined number (for example, within a data transfer cycle indicating one section in which data is transferred) 8) The width of the data transfer cycle is determined so that the number of clocks of the reception clock is greater. This predetermined number is the number by which the data receiving device 8 that receives the data in the time chart shown in FIG. This predetermined number may be appropriately determined by the system.

  In step S <b> 3 of FIG. 3, the data transfer cycle width setting unit 12 of the transmission unit 10 sets the data transfer cycle width 4 determined by the control unit 9 in the data transmission unit 11.

  In step S4 of FIG. 3, the data transmission unit 11 of the transmission unit 10 transmits 1-bit data within one section of data transfer having the data transfer cycle width 4 set by the data transfer cycle width setting unit 12. At this time, the data transmission unit 11 transmits the data transfer cycle signal 5 to the data reception device 8 in synchronization with the transmission clock. In synchronization with the data transfer cycle signal 5, the data is continuously transmitted to the data receiving device 8 as serial data. The data transfer cycle signal 5 is a signal that repeatedly indicates one section (one cycle) of data transfer when transferring data continuously.

  In step S5 of FIG. 3, as described with reference to FIG. 4 in the background art section, the data reception device 8 performs data transfer cycle signal 5 (STB of FIG. 4) based on the reception clock (Rcv-CLK of FIG. 4). Signal) from the data transmission device 7. The width of one cycle of the data transfer cycle signal 5 is determined in step S2 so that the number of reception clocks is greater than or equal to a predetermined number (for example, eight) in one cycle.

  That is, the data receiving device 8 receives the data transfer cycle signal 5 in synchronization with a reception clock having such a frequency that a predetermined number (for example, eight) of clocks are included in one cycle of the data transfer cycle signal 5.

  In step S6 of FIG. 3, as described with reference to FIG. 4 in the background art section, the data receiving device 8 repeatedly generates a strobe pulse (STBpulse of FIG. 4) every cycle of the data transfer cycle signal 5. Data is continuously received from the data transmitter 7 by the strobe pulse. For example, the data transfer cycle signal 5 delayed by one period of the reception clock is reproduced by three F / Fs. Then, a strobe pulse is created based on these reproduced data transfer cycle signals 5 (STBF1 signal). One-bit data transmitted by the data transmission device 7 is acquired using this strobe pulse as a strobe signal, and serial data is received by continuously receiving this data.

  Therefore, according to the second embodiment of the present invention, the data transmission cycle is set so that the data transmission device 7 includes a predetermined number (for example, eight) or more of the number of reception clocks in the data transfer cycle. And the data is transmitted to the data receiving device 8. Then, the data reception device 8 repeatedly generates a strobe pulse for each cycle of the data transfer cycle signal 5 based on the reception clock of the data reception device 8, and continuously transmits serial data from the data transmission device 7 by this strobe pulse. Receive. For this reason, the data receiving device 8 receives data with the data transfer cycle signal 5 in which the number of clocks of the reception clocks equal to or greater than a predetermined number is included in the data transfer cycle.

  As described above, according to the second embodiment of the present invention, serial data can be transmitted without causing bit missing in the data receiving device 8 with the simple configuration as described above. Then, the serial data can be transmitted with the reception clock of the data reception device 8, that is, with the frequency suitable for the data reception device 8.

  In the above description, the case of the data transmission device 7 having one transmission unit and one data reception device corresponding thereto is described. However, a plurality of transmission units and data reception devices may be provided, and a plurality of data reception devices may correspond to the plurality of transmission units. That is, the control unit of the data transmission device determines a plurality of data transfer cycle widths respectively corresponding to the plurality of data reception devices based on the frequency information of the reception clocks of the plurality of data reception devices. The plurality of transmission units of the data transmission device respectively transmit one data to each of the plurality of data reception devices in each section of the data transfer, each having a plurality of data transfer cycle widths determined by the control unit. Anyway.

  Also, in the above description, there is a control unit in the data transmission device, and this control unit uses the clock information of the reception clock of the data reception device based on the frequency information of the reception clock of the predetermined number of reception clocks or more. Operations such as determining the width of the data transfer cycle so that the number is included are performed. However, the data transmission device may be connected to a host device outside the device, and the host device may be caused to execute the function of the control unit instead of the control unit.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
Based on the reception clock, it receives a data transfer cycle signal that repeatedly indicates a transfer period in which data is transferred continuously, repeatedly generates a strobe pulse from this data transfer cycle signal, and continuously uses this strobe pulse. In the data transmission device that transmits the data transfer cycle signal in synchronization with a transmission clock toward the data reception device that receives the data, and continuously transmits the data in synchronization with the data transfer cycle signal. ,
The data transmission device includes:
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A control unit for determining the width of
A transmission unit for transmitting one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the control unit;
A data transmission device comprising:

(Appendix 2)
The transmitter is
A reception clock frequency detection unit that detects the frequency information of the reception clock from the data reception device and outputs the detected frequency information to the control unit;
The control unit receives the frequency information from the reception clock frequency detection unit, and determines the data transfer cycle width based on the frequency information.
A data transmitting apparatus characterized by that.

(Appendix 3)
The controller is
The frequency information of the reception clock is acquired by an operation from the outside of the data transmission device, and the data transfer cycle width is determined based on the acquired frequency information.
A data transmitting apparatus characterized by that.

(Appendix 4)
The transmission unit transmits the data transfer cycle signal while synchronizing with the transmission clock, and transmits one bit of data in one cycle section of the data transfer cycle signal.

(Appendix 5)
The transmitter is
A data transfer cycle width setting unit for setting the data transfer cycle width determined by the control unit;
A data transmission unit for transmitting the data based on the data transfer cycle width set by the data transfer cycle width setting unit;
A data transmission device comprising:

(Appendix 6)
The data transmitting device and the data receiving device that receives the data transmitted by the data transmitting device;
The data reception device generates the strobe pulse from the data transfer cycle signal transmitted by the transmission unit in synchronization with the reception clock, and acquires the data transmitted by the transmission unit using the strobe pulse. What I did,
A data transfer device.

(Appendix 7)
A plurality of the data receiving devices;
The data transmitting device determines the plurality of data transfer cycle widths respectively corresponding to the plurality of data receiving devices based on frequency information of the reception clocks of the plurality of data receiving devices; and
A plurality of the data receiving apparatuses, each transmitting one piece of the data to each of the plurality of data receiving apparatuses within each one section of the data transfer having the plurality of data transfer cycle widths determined by the control unit. A plurality of transmission units corresponding to each of the transmission units;
A data transfer device comprising:

(Appendix 8)
The data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in a data transfer cycle indicating a section in which data is transferred by the data transmission device based on the frequency information of the reception clock of the data reception device. Determine the width of
Data that repeatedly indicates one section of transfer in which data is transmitted continuously while transmitting one data within the one section of the data transfer having the determined data transfer cycle width by the data transmitting device. In synchronization with a transfer cycle signal, the data is continuously transmitted to the data receiving device,
The data receiving device receives a data transfer cycle signal from the data transmitting device on the basis of the reception clock, repeatedly generates a strobe pulse for each cycle of the data transfer cycle signal, and uses the strobe pulse to continuously output the data. A data transfer method characterized by receiving from a data transmitting device.

(Appendix 9)
Based on the reception clock, it receives a data transfer cycle signal that repeatedly indicates one transfer period in which data is transferred continuously, generates a strobe pulse repeatedly from the data transfer cycle signal, and continuously uses this strobe pulse. In the data transmission device that transmits the data transfer cycle signal in synchronization with a transmission clock toward the data reception device that receives the data, and continuously transmits the data in synchronization with the data transfer cycle signal.
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A host device that determines the width of the
The data transmission device including a transmission unit that transmits one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the host device;
A data transmission device comprising:

(Appendix 10)
The transmission unit transmits the data transfer cycle signal while synchronizing with the transmission clock, and transmits one bit of data in one cycle section of the data transfer cycle signal.

(Appendix 11)
The transmitter is
A reception clock frequency detector that detects the frequency information of the reception clock from the data reception device and outputs the detection information to the host device;
The host device receives the frequency information from the reception clock frequency detector, and determines the data transfer cycle width based on the frequency information.
A data transmitting apparatus characterized by that.

(Appendix 12)
The host device is
The frequency information of the reception clock is acquired by an operation from the outside of the data transmission device, and the data transfer cycle width is determined based on the acquired frequency information.
A data transmitting apparatus characterized by that.

(Appendix 13)
The transmitter is
A data transfer cycle width setting unit for setting the data transfer cycle width determined by the host device;
A data transmission unit for transmitting the data based on the data transfer cycle width set by the data transfer cycle width setting unit;
A data transmission device comprising:

(Appendix 14)
The data transmitting device and the data receiving device that receives the data transmitted by the data transmitting device;
The data reception device generates the strobe pulse from the data transfer cycle signal transmitted by the transmission unit in synchronization with the reception clock, and acquires the data transmitted by the transmission unit based on the strobe pulse. What
A data transfer device.

(Appendix 15)
A plurality of the data receiving devices;
The data transmitting device determines the plurality of data transfer cycle widths respectively corresponding to the plurality of data receiving devices based on frequency information of the reception clocks of the plurality of data receiving devices;
Each of the plurality of data receiving apparatuses transmits one piece of the data to each of the plurality of data receiving apparatuses within each section of the data transfer having each of the plurality of data transfer cycle widths determined by the host apparatus. A plurality of corresponding transmitters;
A data transfer device comprising:

DESCRIPTION OF SYMBOLS 1 Data transmission apparatus 2 Control part 3 Transmission part 4 Data transfer cycle width 5 Data transfer cycle signal 6 Data transfer apparatus 7 Data transmission apparatus 8 Data reception apparatus 9 Control part 10 Transmission part 11 Data transmission part 12 Data transfer cycle width setting part 13 Receive clock frequency detector 15 Data transmitter 16 Data receiver 17 Data transmitter 18 Data receiver

Claims (10)

Based on the reception clock, it receives a data transfer cycle signal that repeatedly indicates a transfer period in which data is transferred continuously, repeatedly generates a strobe pulse from this data transfer cycle signal, and continuously uses this strobe pulse. In the data transmission device that transmits the data transfer cycle signal in synchronization with a transmission clock toward the data reception device that receives the data, and continuously transmits the data in synchronization with the data transfer cycle signal. ,
The data transmission device includes:
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A control unit for determining the width of
A transmission unit for transmitting one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the control unit;
A data transmission device comprising: The transmitter is
A reception clock frequency detection unit that detects the frequency information of the reception clock from the data reception device and outputs the detected frequency information to the control unit;
The control unit receives the frequency information from the reception clock frequency detection unit, and determines the data transfer cycle width based on the frequency information.
The data transmission device according to claim 1. The controller is
The data transmission apparatus according to claim 1, wherein the frequency information of the reception clock is acquired by an operation from outside the data transmission apparatus, and the data transfer cycle width is determined based on the acquired frequency information.   The transmission unit transmits the data transfer cycle signal in synchronization with the transmission clock, and transmits 1-bit data in one cycle interval of the data transfer cycle signal. 2. The data transmission device according to 2 or 3. The transmitter is
A data transfer cycle width setting unit for setting the data transfer cycle width determined by the control unit;
A data transmission unit for transmitting the data based on the data transfer cycle width set by the data transfer cycle width setting unit;
The data transmission device according to claim 4, further comprising: The data transmission device according to claim 4 or 5, and the data reception device that receives the data transmitted by the data transmission device,
The data reception device generates the strobe pulse from the data transfer cycle signal transmitted by the transmission unit in synchronization with the reception clock, and acquires the data transmitted by the transmission unit using the strobe pulse. What I did,
A data transfer device. A plurality of the data receiving devices;
The data transmitting device determines the plurality of data transfer cycle widths respectively corresponding to the plurality of data receiving devices based on frequency information of the reception clocks of the plurality of data receiving devices; and
A plurality of the data receiving apparatuses, each transmitting one piece of the data to each of the plurality of data receiving apparatuses within each one section of the data transfer having the plurality of data transfer cycle widths determined by the control unit. A plurality of transmission units corresponding to each of the transmission units;
The data transfer apparatus according to claim 6, further comprising: The data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in a data transfer cycle indicating a section in which data is transferred by the data transmission device based on the frequency information of the reception clock of the data reception device. Determine the width of
Data that repeatedly indicates one section of transfer in which data is transmitted continuously while transmitting one data within the one section of the data transfer having the determined data transfer cycle width by the data transmitting device. In synchronization with a transfer cycle signal, the data is continuously transmitted to the data receiving device,
The data receiving device receives a data transfer cycle signal from the data transmitting device on the basis of the reception clock, repeatedly generates a strobe pulse for each cycle of the data transfer cycle signal, and uses the strobe pulse to continuously output the data. A data transfer method characterized by receiving from a data transmitting device. Based on the reception clock, it receives a data transfer cycle signal that repeatedly indicates one transfer period in which data is transferred continuously, generates a strobe pulse repeatedly from the data transfer cycle signal, and continuously uses this strobe pulse. In the data transmission device that transmits the data transfer cycle signal in synchronization with a transmission clock toward the data reception device that receives the data, and continuously transmits the data in synchronization with the data transfer cycle signal.
Based on the frequency information of the reception clock of the data reception device, the data transfer cycle so that the number of clocks of the reception clock equal to or greater than a predetermined number is included in the data transfer cycle indicating one section in which the data is transferred. A host device that determines the width of the
The data transmission device including a transmission unit that transmits one piece of the data within the one section of the data transfer having the data transfer cycle width determined by the host device;
A data transmission device comprising:   The transmission unit transmits the data transfer cycle signal in synchronization with the transmission clock, and transmits one-bit data in one cycle section of the data transfer cycle signal. Data transmission device.

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