JP4025113B2 - Wireless transmission device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wireless transmission device that transmits video signals, audio signals, and the like via a wireless line, and in particular, to ensure synchronization of signals transmitted between a transmitting side and a receiving side via an asynchronous wireless transmission line. About.
[0002]
[Prior art]
In recent years, wireless local area networks (hereinafter referred to as LANs) represented by IEEE802.11 have advantages such as a high degree of freedom in installation locations of devices instead of conventional wired LANs such as Ethernet (registered trademark). It has become widespread. In addition, wireless transmission devices that transmit video signals, audio signals, and the like using a wireless LAN have become widespread. Hereinafter, a conventional wireless transmission device will be described.
[0003]
FIG. 12 is a block diagram showing a configuration of a conventional wireless transmission apparatus. In FIG. 12, 10A is a wireless master device that encodes and modulates an input video signal and transmits it as a radio wave of a predetermined format, and 10B is a wireless slave device that receives the radio wave, demodulates it, decodes it, and outputs a video signal. .
The wireless master unit 10A includes a video signal encoding unit 400A, a communication protocol processing unit 600A, a MAC (Media Access Control) processing unit 700A, an RF unit 800A, and an antenna 30A. Connected through.
The wireless slave device 10B includes a video signal decoding unit 500B, a communication protocol processing unit 600B, a MAC processing unit 700B, an RF unit 800B, and an antenna 30B.
Both the wireless master device 10A and the wireless slave device 10B are capable of bidirectional communication, but only one-way transmission paths are shown for the sake of simplicity of explanation.
[0004]
FIG. 13 is a timing diagram showing the timing of signals transmitted on the wireless line.
FIG. 14 is a block diagram illustrating an internal configuration of the MAC processing unit 700A of the wireless master device 10A and the MAC processing unit 700B of the wireless slave device 10B.
In FIG. 14A, 704A is a frame assembly unit, 701A is a clock generation unit, 702A is a beacon timer unit, 703A is a beacon generation unit, 705A is a frame analysis unit, and 706A is a received data processing unit.
In FIG. 14B, 704B is a frame assembly unit, 701B is a clock generation unit, 702B is a beacon timer unit, 703B is a beacon generation unit, 705B is a frame analysis unit, and 706B is a received data processing unit.
[0005]
The operation of the conventional radio transmission apparatus configured as described above will be described below.
First, the operation of the wireless master device 10A in FIG. 12 will be described. A video signal is input from the outside to the wireless master device 10A. The input video signal is compressed and encoded in a predetermined format by the video signal encoding unit 400A. Usually, when a video signal is transmitted, it is encoded using the MPEG2-TS format for the purpose of reducing the amount of data transmission and transmitting clock information. The encoded video signal is packetized in the MPEG2-TS packet format.
[0006]
The MPEG2-TS packet is input to the communication protocol processing unit 600A, further packetized based on a predetermined communication protocol, and a header necessary for transmission is added. As the communication protocol, TCP / IP for realizing reliable data transmission, UDP / IP suitable for transmission of stream data, or the like is used. MPEG2-TS packets are packetized into an IP packet format. Is done.
The IP packet is input to the MAC processing unit 700A and assembled as a MAC packet based on a predetermined wireless communication method. For the configuration of the MAC packet, a method defined by a wireless LAN standard such as IEEE 802.11 is used.
[0007]
Data assembled in the MAC packet format is input to the RF unit 800A. The RF unit 800A performs predetermined modulation and transmits data as a radio wave having a predetermined frequency via the antenna 30A. As the modulation method, quadrature modulation and spread spectrum or OFDM are used. The 2.4G band, 5G band, etc. are used for the frequency. The video signal input in this way is sent out on the wireless communication line by a predetermined method.
[0008]
Next, the operation of the wireless slave device 10B in FIG. 12 will be described. In the wireless slave device 10B, the radio wave (data) received by the antenna 30B is input to the RF unit 800B.
The RF unit 800B selects a desired frequency, demodulates the received data, converts the received data into a baseband signal, that is, data in a MAC packet format, and outputs the data to the MAC processing unit 700B.
[0009]
The MAC processing unit 700B analyzes the input data in the MAC packet format, converts it into an IP packet, and outputs it to the communication protocol processing unit 600B.
The communication protocol processing unit 600B extracts the MPEG2-TS packet from the input IP packet and outputs it to the video signal decoding unit 500B.
The video signal decoding unit 500B decodes the input MPEG2-TS packet, decompresses it, and outputs it as a video signal. In this way, the video signal input from the wireless master device 10A is transmitted to the wireless slave device 10B via the wireless communication line, and is decoded, expanded, and externally output in the wireless slave device 10B.
[0010]
Next, the timing of signals transmitted on the wireless line will be described with reference to FIG. In FIG. 13, a beacon is a control signal transmitted from the wireless master device 10 </ b> A, and is transmitted at a constant interval (cycle) of about several ms to 1 s. The beacon includes control information such as an identification number for identifying the wireless master device 10A and a timer value provided in the wireless master device 10A.
The use purpose of this beacon is that the wireless slave device 10B can identify the wireless master device 10A based on the identification number included in the beacon, and the transmission / reception of the wireless master device 10A and the wireless slave device 10B with reference to the output timing of the beacon. In addition, by adjusting the internal timer of the wireless slave device 10B to the timer value of the wireless master device 10A included in the beacon, video data can be transmitted and received between the wireless master device 10A and the wireless slave device 10B. In the case where it is not necessary to perform the operation, the wireless slave device 10B is operated intermittently for the beacon reception timing to save power.
[0011]
Video data is sent at the timing between two adjacent beacons. IEEE802.11 employs the CSMA / CA method, and when data is transmitted, it first receives and confirms whether the wireless line is free, that is, whether another wireless transmission device is transmitting, If it is not available, the transmission is performed. If it is not available, it is confirmed that the transmission of another wireless transmission device is completed, and then the data is transmitted.
Therefore, when there are a plurality of wireless slave units 10B, when the wireless line is in use for other communication, the transmission of the signal is completed and the transmission of the wireless line is awaited. A transmission delay may occur depending on the usage situation.
[0012]
Next, the operation when the wireless master device 10A transmits a beacon, the wireless slave device 10B receives the beacon, and synchronizes the internal timer of the wireless master device 10A and the internal timer of the wireless slave device 10B with reference to FIG. I will explain.
Beacon transmission / reception is performed by the MAC processing unit 700A of the wireless master device 10A and the MAC processing unit 700B of the wireless slave device 10B.
[0013]
First, an operation when the wireless master device 10A transmits a beacon will be described. The clock generation unit 701A generates a clock signal for generating the timing for transmitting a beacon and outputs it to the beacon timer unit 702A.
The beacon timer unit 702A counts a clock signal, and includes, for example, a counter of about 64 bits.
The beacon generation unit 703A refers to the count value (timer value) output from the beacon timer unit 702A, and detects that the timer value has changed to a predetermined value. And the timer value output from the beacon timer unit 702A are output to the frame assembling unit 704A. The predetermined value here is a value determined by the relationship with the clock signal of the clock generation unit 701A, and a desired beacon transmission cycle is set by this value. The frame assembly unit 704A stores the control information in a predetermined MAC frame and outputs it to the RF unit 800A. Thus, a beacon signal storing control information is transmitted at a predetermined cycle.
[0014]
Next, an operation when the wireless slave device 10B receives a beacon will be described.
In the wireless slave device 10B, the received signal output from the RF unit 800B is analyzed by the frame analysis unit 705B to determine whether the signal is addressed to the own device. If the signal is not addressed to the own device, the signal is discarded. If the signal is addressed to the own device, the received data is output to the received data processing unit 706B.
When the received data is a beacon, the received data processing unit 706B extracts control information included in the received data, extracts timer value information from the control information, and outputs the information to the beacon timer unit 702B. This timer value is the timer value of the wireless master device 10A stored in the beacon by the wireless master device 10A.
[0015]
The beacon timer unit 702B of the wireless slave device 10B counts the clock signal output from the clock generation unit 701B in the same manner as the beacon timer unit 702A of the wireless master device 10A. The difference from the wireless master device 10A is that the count value of the beacon timer unit 702B of the wireless slave device 10B is rewritten by the timer value output from the received data processing unit 706B. By this rewriting, the count values of the beacon timer unit 702A of the wireless master device 10A and the beacon timer unit 702B of the wireless slave device 10B match.
[0016]
Each time the wireless slave device 10B receives a beacon, the beacon timer unit 702B is rewritten with the timer value of the wireless master device 10A included in the received beacon, thereby the internal timer of the wireless master device 10A and the internal of the wireless slave device 10B. The timer can be synchronized.
Since the internal timer of the wireless master device 10A and the internal timer of the wireless slave device 10B are synchronized, the wireless slave device 10B performs the reception operation of the wireless slave device 10B only at the timing when the beacon is transmitted from the wireless master device 10A. In addition, operation control such as reducing power consumption by stopping the operation at other timings becomes possible.
[0017]
[Problems to be solved by the invention]
The conventional wireless transmission device is configured as described above, and is a convenient device that can transmit a video signal from the wireless master device 10A to the wireless slave device 10B without laying a new wired transmission line. It was. However, the video signal reproduced by the wireless slave device 10B may not be normally reproduced due to the influence of a change in communication state peculiar to the wireless line, propagation delay, communication protocol processing delay, and the like.
[0018]
The video signal is transmitted in the MPEG2-TS format. In the transmission of the MPEG2-TS packet through the wireless line, the timing at which the video signal encoding unit 400A outputs the MPEG2-TS packet, and the MPEG2-TS packet is decoded by the video signal. If the timing input to unit 500B is not accurately reproduced, the video signal cannot be normally reproduced on the receiving side.
[0019]
This is because the MPEG2-TS packet has clock information serving as a reference clock for decoding in the packet, and a correct reference clock cannot be reproduced unless it is transmitted at the correct timing.
However, in the wireless transmission device having such a configuration, there are cases where the processing delay time in the communication protocol processing unit is shortened or lengthened.
The processing performed in the communication protocol processing unit is extremely complicated when implemented in hardware, so it is implemented in software using a CPU or the like. However, the processing time for software may be set to a constant value. Have difficulty.
[0020]
In addition, in the wireless communication line, the propagation delay changes because the propagation path changes in a non-constant manner, for example, radio waves are reflected by surrounding structures.
Further, when the quality deteriorates due to interference or interference from other wireless communication devices, complementary processing such as detecting an error in the data to be transmitted and resending the data again is performed by the MAC processing unit. In this case, a large delay time occurs because the data once transmitted is sent again later.
[0021]
Therefore, in such a case, the output timing of the MPEG2-TS packet by the video signal encoding unit 400A is not accurately reproduced when input to the video signal decoding unit 500B, and the video signal is normally reproduced on the receiving side. There was a problem that could not be done.
[0022]
The present invention has been made in order to solve the above-described problems. Even when a change in delay time due to communication protocol processing, a change in transmission delay time due to the state of a wireless line, or the like occurs, a video signal has the correct timing. It is an object of the present invention to provide a wireless transmission device that can reproduce data.
[0023]
[Means for Solving the Problems]
In order to solve the above problems, a wireless transmission device according to the present invention has the following configuration.
The invention according to claim 1 is a wireless master device that transmits a video signal as packet data between a wireless slave device and a wireless slave device connected by a wireless line, Used to synchronize between the internal timer of the wireless master unit and the internal timer of the wireless slave unit A time information generating unit for generating first time information; and the first time information. Including control signals A time information transmitter that transmits intermittently at a predetermined cycle; A video signal encoding unit that encodes a video signal and outputs the packet data, and a packet signal of the video signal is output from the video signal encoding unit. The first time information or time information derived based on the first time information, As a time stamp, Video signal For each packet data A time information adding unit to be added to, A packet data transmission unit for transmitting packet data of a video signal output from the time information addition unit; It is a radio | wireless parent machine characterized by having.
According to the present invention, time information on the wireless master device side can be added to a data packet of a video signal and transmitted to the wireless slave device.
[0024]
The invention according to claim 2 is a wireless slave device that receives packet data of a video signal transmitted between a wireless master device and a wireless slave device connected by a wireless line, and the wireless master device receives a predetermined data from the wireless master device. Sent intermittently at periodic intervals , A control signal including first time information used to synchronize the internal timer of the wireless master and the internal timer of the wireless slave Enter Extract the first time information from the control signal A first PLL unit for generating second time information for reproducing the first time information; A receiver for receiving packet data of a video signal to which a time stamp, which is time information derived based on the first time information or the first time information, transmitted from the wireless master device, and a video signal; The added time stamp is extracted and generated by the extracted time stamp and the first PLL unit. Compared with the second time information, and depending on the comparison result, Video signal packet data A first time information comparison unit for controlling the output timing of A video signal decoding unit for inputting and decoding packet data of the video signal at an output timing controlled by the first time information comparison unit; It is a wireless cordless handset characterized by having.
According to the present invention, on the wireless slave unit side, the timing is based on the time information added to the packet data of the video signal on the wireless master unit side. Video signal packet data Can be output.
[0025]
The invention according to claim 3 includes a second PLL unit that generates time information with higher accuracy than the first time information based on the first time information, and the time information adding unit includes The time information generated by the second PLL unit is used for the video signal to be transmitted. Packet data The wireless master device according to claim 1, further comprising:
According to the present invention, the time information added to the packet data of the video signal on the wireless master side becomes more accurate.
[0026]
According to a fourth aspect of the present invention, there is provided a wireless transmission device comprising the wireless parent device according to the first or third aspect and the wireless child device according to the second aspect.
According to the present invention, a stream such as a video signal can be synchronously transmitted between a wireless master device and a wireless slave device.
[0027]
According to a fifth aspect of the present invention, at least the video signal packet data is added to the packet data. Time stamp The wireless slave device according to claim 2, wherein the wireless slave device is retransmitted to the wireless master device.
According to the present invention, the wireless master device can obtain time information required for data transmission. At this time, for example, the wireless slave unit retransmits only the received data packet to which the time information is added, the time information and the packet ID code, or the time information.
[0028]
The invention according to claim 6 is retransmitted from the wireless slave unit Time stamp Based on the comparison result of the second time information comparison unit comparing the first time information or the time information derived based on the first time information, and the second time information comparison unit. A first offset calculation unit that calculates an offset value and generates time information obtained by correcting the first time information or time information derived based on the first time information with the offset value; The time information adding unit includes the time information generated by the first offset calculating unit, As a time stamp, Packet of video signal to send data The wireless master device according to claim 1, further comprising:
According to the present invention, it is possible to correct the time information added to the data packet of the video signal by using the data transmission time between the wireless master device and the wireless slave device.
[0029]
The invention according to claim 7 is a wireless transmission device comprising the wireless master device according to claim 6 and the wireless slave device according to claim 5.
According to the present invention, it is possible to perform synchronous transmission of a stream such as a video signal that is not easily affected by a change in data transmission time between the wireless master device and the wireless slave device.
[0030]
The invention according to claim 8 provides: Of the video signal packet data The For video signal decoding The received data buffer unit temporarily holds until output, and the received data buffer unit holds the received data buffer unit. Video signal packet data A reception data size detection unit that detects the size of the received data (hereinafter referred to as “reception data size”), and the reception data size detected by the reception data size detection unit and the reception data size are preset. 3. The wireless slave device according to claim 2, wherein reception data buffer information including at least one of a comparison result with a reference data size that has been transmitted is transmitted to the wireless master device.
According to the present invention, the wireless master device can obtain information about the state of the reception data buffer of the wireless slave device.
[0031]
The invention according to claim 9 is temporarily stored in the reception data buffer unit of the wireless slave unit transmitted from the wireless slave unit. Video signal packet data of received data An offset value is calculated based on received data buffer information including at least one of a size and a comparison result between the received data size and a preset reference data size, and the first time information or the first 2. The wireless master device according to claim 1, further comprising a first offset calculation unit that generates time information obtained by correcting time information derived based on time information of 1 with the offset value. .
According to the present invention, the time information added to the data packet of the video signal can be corrected according to the state of the reception data buffer of the wireless slave unit.
[0032]
A tenth aspect of the present invention is a wireless transmission device including the wireless parent device according to the ninth aspect and the wireless child device according to the eighth aspect.
According to the present invention, it is possible to prevent a situation in which output is not possible due to data overflow in the reception data buffer of the wireless slave unit or the absence of reception data packets.
[0033]
The invention according to claim 11 Video signal packet data The received data buffer unit temporarily holding until the data is output and the received data buffer unit Video signal packet data At least one of a received data size detector that detects the received data size, a received data size detected by the received data size detector, and a comparison result between the received data size and a preset reference data size And a second offset calculation unit that calculates an offset value based on the received data buffer information including the first time information comparison unit, wherein the first time information comparison unit corrects the second time information with the offset value. Time information obtained by Video signal packet data Is compared with the time information added to the Video signal packet data The wireless slave device according to claim 2, wherein the output timing is controlled.
According to the present invention, the data overflow of the reception data buffer of the wireless slave unit or Video signal packet data It is possible to prevent a state in which output cannot be performed due to the absence of.
[0034]
The invention according to claim 12 is a reception error frequency detection unit that detects a frequency at which reception data has an error, and a second offset that calculates an offset value based on the reception error frequency detected by the reception error frequency detection unit. A first calculating unit, and the first time information comparing unit includes time information obtained by correcting the second time information with the offset value; Video signal packet data Is compared with the time information added to the Video signal packet data The wireless slave device according to claim 2, wherein the output timing is controlled.
According to the present invention, it is possible to perform synchronous transmission of a stream such as a video signal that is not easily affected by a change in a propagation state of a wireless line between a wireless master device and a wireless slave device.
[0035]
A thirteenth aspect of the present invention is a reception field strength measurement unit that measures a reception field strength value, and a second offset calculation unit that calculates an offset value based on the reception field strength value measured by the reception field strength measurement unit. The first time information comparison unit further includes time information obtained by correcting the second time information with the offset value, and Video signal packet data Is compared with the time information added to the Video signal packet data The wireless slave device according to claim 2, wherein the output timing is controlled.
According to the present invention, it is possible to perform synchronous transmission of a stream such as a video signal that is not easily affected by a change in a propagation state of a wireless line between a wireless master device and a wireless slave device.
[0036]
The invention described in claim 14 is the wireless master device according to claim 1, further comprising a transmission cycle setting unit that changes a transmission cycle of the time information transmission unit.
According to the present invention, it is possible to adjust the time until the wireless master device can perform stream transmission to the wireless slave device.
[0037]
The invention according to claim 15 further includes a PLL lock detection unit that detects that the first PLL unit is locked and generates PLL lock information indicating that the first PLL unit is locked, The wireless slave device according to claim 2, wherein the PLL lock information is notified to the wireless master device.
According to the present invention, the wireless master device can obtain information on the state of the PLL of the wireless slave device.
[0038]
The invention according to claim 16 is the transmission cycle of the time information transmitter based on the PLL lock information indicating that the first PLL unit sent from the wireless slave is locked. The radio base unit according to claim 14, wherein the radio base unit is changed.
According to the present invention, it is possible to adjust the time until the wireless master device can perform stream transmission to the wireless slave device in accordance with the PLL state of the wireless slave device.
[0039]
The invention described in claim 17 is a wireless transmission apparatus comprising the wireless master device described in claim 16 and the wireless slave device described in claim 15.
According to the present invention, the wireless slave device can reliably receive the stream signal transmitted by the wireless master device.
[0040]
The invention according to claim 18 further includes a reception field strength measurement unit for measuring a reception field strength value, and transmits the reception field strength value to the wireless master unit. It is a wireless slave unit.
According to the present invention, the wireless master device can obtain the received electric field strength value of the wireless slave device.
[0041]
The invention according to claim 19 is characterized in that the transmission cycle setting unit changes the transmission cycle of the time information transmission unit based on the received electric field strength value of the wireless slave unit transmitted from the wireless slave unit. The wireless master device according to claim 14.
According to the present invention, the transmission cycle of the wireless master device can be adjusted according to the received electric field strength value.
[0042]
The invention according to claim 20 is a wireless transmission device comprising the wireless master device according to claim 19 and the wireless slave device according to claim 18.
According to the present invention, when the received electric field strength is weak, by shortening the beacon period, it is possible to reduce the number of times the beacon period is missed and to prevent the PLL from coming off. Further, when the received electric field strength is strong, the problem of the decrease in transmission throughput and the energy consumption can be solved by setting the beacon period longer.
[0043]
The invention according to claim 21 further includes a reception error frequency detection unit that detects a frequency at which the received data causes an error, and transmits the reception error frequency detected by the reception error frequency detection unit to the wireless master device. The wireless slave device according to claim 2, wherein:
According to the present invention, the wireless master device can obtain the frequency of occurrence of reception errors of the wireless slave device.
[0044]
The invention according to claim 22 is characterized in that the transmission cycle setting unit changes the transmission cycle of the time information transmission unit based on the reception error frequency of the wireless slave unit transmitted from the wireless slave unit. The wireless master device according to claim 14.
According to the present invention, the transmission cycle of the wireless master device can be adjusted according to the frequency of occurrence of reception errors.
[0045]
The invention described in claim 23 is a wireless transmission device comprising the wireless master device described in claim 22 and the wireless slave device described in claim 21.
According to the present invention, when the frequency of occurrence of reception errors is high, the beacon period can be shortened to reduce the number of times the beacon period is missed and to prevent the PLL from coming off. Also, when the frequency of occurrence of reception errors is low, the problem of a decrease in transmission throughput and energy consumption can be solved by setting a long beacon period.
[0046]
DETAILED DESCRIPTION OF THE INVENTION
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments specifically showing preferred modes for carrying out the present invention will be described below with reference to the drawings.
[0047]
Example 1
FIG. 1 is a block diagram illustrating a configuration of a wireless transmission device according to the first embodiment.
In FIG. 1, the wireless master device 10A is a wireless master device, and the wireless slave device 10B is a wireless slave device.
In the wireless master device 10A, the clock generation unit 701A and the beacon timer unit 702A constitute a time information generation unit. The beacon generation unit 703A, the frame assembly unit 704A, and the RF unit 800A constitute a time information transmission unit (the frame assembly unit 704A and the RF unit 800A also serve as a packet data transmission unit for video signals). The time stamp adding unit 905A constitutes a time information adding unit.
In the wireless slave device 10B, Received data processing unit 706B, beacon timer unit 702B, The PLL processing unit 904B and the time stamp timer unit 903B constitute a first PLL unit. Time stamp extraction unit 901B and The time stamp comparison unit 902B constitutes a first time information comparison unit.
[0048]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the conventional radio transmission apparatus (FIGS. 12 and 14), or an equivalent part.
In the wireless transmission device according to the first embodiment, a time stamp adding unit 905A and a reception data buffer unit 907A are newly added to the wireless master device 10A, and a time stamp extracting unit 901B, a time stamp comparing unit 902B, A time stamp timer unit 903B, a PLL processing unit 904B, a time stamp adding unit 905B, a received data buffer unit 907B, and an initial value setting unit 910B are newly added.
[0049]
The radio transmission apparatus according to the first embodiment configured as described above adds a time stamp to a video signal transmitted on the transmission side and transmits it, and uses the time stamp on the reception side to synchronize with the timing at the time of transmission. An operation different from the conventional example of reproducing a video signal is performed. The operation of the wireless transmission device according to the first embodiment will be described below.
[0050]
First, an operation of adding a time stamp to the MPEG2-TS packet output from the video signal encoding unit 400A in the wireless master device 10A will be described.
Time stamp output from the beacon timer unit 702A is input to the time stamp adding unit 905A. The time information is a value obtained by counting the clock output from the clock generation unit 701A by the beacon timer unit 702A. When the MPEG2-TS packet output from the video signal encoding unit 400A is input to the time stamp adding unit 905A, the time stamp adding unit 905A displays the time information output from the beacon timer unit 702A at that time by the MPEG2-TS packet. It is added to the TS packet and output to the communication protocol processing unit 600A.
[0051]
In the wireless transmission device according to the first embodiment, a time axis based on time information output from the beacon timer unit 702A is assumed. The time information is added as a time stamp at the timing when the video signal encoding unit 400A outputs the MPEG2-TS packet.
Thus, the time information output from the beacon timer unit 702A is added to the MPEG2-TS packet as a time stamp with reference to the timing at which the video signal encoding unit 400A outputs the MPEG2-TS packet.
The MPEG2-TS packet with the time stamp added to the communication protocol processing unit 600A is output from the antenna 30A to the wireless communication line by the same operation as in the conventional example.
[0052]
Here, an example of data packet specifications during communication (common to all embodiments of the present invention) will be described with reference to FIGS. 15 to 18.
FIG. 15 shows a format of a data packet used in communication in the embodiment of the present invention.
In FIG. 15, a data packet is composed of a wireless header 1501, a MAC header 1502, a frame body 1503, and an FCS (Frame Check Sequence) 1504 defined by IEEE 802.11.
The data length of the frame body 1503 is a maximum of 2304 bytes (variable according to the content of data to be transmitted), and is composed of an IP header 1505, a UDP header 1506, an AV information header 1507, an AV port header 1508, and data 1509. Among these, the formats of the AV information header 1507, the AV port header 1508, and the data 1509 are unique in the embodiment of the present invention.
[0053]
The format of the data 1509 changes according to the contents of the AV information header 1507 and the AV port header 1508. Further, the IP header 1505 and the UDP header 1506 are not necessarily required, but are necessary when data is transmitted based on the IP protocol.
Next, the structure of the AV information header 1507 will be described with reference to FIG.
The data length of the AV information header 1507 is 8 bytes, the protocol version 1601 of 1 byte length, the packet identification flag 1602 of 1 bit length, the extended information flag 1603 of 1 bit length, the format ID 1604 of 6 bit length, and the byte length of 1 byte The copyright management information 1605 includes a 1-byte data block size 1606, a 1-byte data block number 1607, and 3-byte extended information 1608.
[0054]
The protocol version 1601 indicates the version number of the communication protocol, and is used for distinguishing when the communication protocol method is updated.
The packet identification flag 1602 is set to 0 when data related to video data is transmitted, and is set to 1 when data for other purposes is transmitted. Other uses assume transmission of network configuration information that is not directly related to transmission of video data.
The extended information flag 1603 indicates the presence / absence of extended information 1608. When the extended information flag 1603 is 1, the extended information 1608 exists, and when it is 0, it indicates that it does not exist (in this case, the data length of the AV information header 1507 is 5 bytes).
[0055]
A format ID 1604 indicates the format of video data to be transmitted (for example, MPEG2-TS). The format ID 1604 has the same format as the FMT (Format ID) of the CIP (Common isochronous packet) header defined in IEEE 1394-1995. For example, when the video data is MPEG2-TS, the binary data is “100,000”. .
The copyright management information 1605 indicates management information related to copyright indicating whether the data to be transmitted is copyable or prohibited. The copyright management information 1605 is composed of 2-bit EMI (Encryption Mode Indicator) defined by Digital Transmission Content Protection Specification Volume 1 (Informational Version) and 1-bit Odd / Even bit. The remaining 5 bits are an extension area for the future.
[0056]
The data block size 1606 indicates the number of bytes per block of the data block stored in the data 1509 (192 bytes in this embodiment).
The data block number 1607 indicates the number of data blocks stored in the data 1509.
The extension information 1608 has the same format as the FDF (Format Dependent Field) of the CIP header defined by IEEE 1394-1995 and SYT. When the value of the extension information flag 1603 is 0, the extension information 1608 is not included in the AV information header (to reduce the transmission data amount).
[0057]
Next, the structure of the AV port header 1508 will be described with reference to FIG.
The data length of the AV port header 1508 is 4 bytes, and is composed of a 2-byte spare 1701, a 1-byte output AV port 1702, and a 1-byte input AV port 1703.
A spare 1701 indicates a spare area for future expansion.
The output AV port 1702 is used for identifying video signal output. The output AV port 1702 includes a 1-bit data identification flag 1704, a 3-bit spare 1705, a 1-bit 1394 flag 1706, and a 3-bit port number 1707.
[0058]
A data identification flag 1704 indicates the type of data stored in the data 1509. When the data identification flag 1704 is 0, it is video data, and when it is 1, it is data for controlling a device connected to the video signal input and a device connected to the video signal output. Control means playback, recording, stop, fast forward, rewind, etc., if the device connected to the video signal input is a VTR, for example, and channel change etc. if the device connected to the video output device is, for example, a TV. .
[0059]
The spare 1705 indicates a spare area for future expansion.
The 1394 flag 1706 is a flag indicating whether a device connected to the video signal input and a device connected to the video signal output have a 1394 interface. When the 1394 flag 1706 is 1, it indicates that there is a 1394 interface, and when it is 0, it indicates that there is no 1394 interface.
The port number 1707 is used to identify video equipment connected to video signal input and video signal output. Thus, for example, data transmission between devices is possible even when the VTR1 and VTR2 are connected to the video signal input of the wireless master device 10A and the VTR and TV are connected to the video signal output of the wireless slave device 10B. Is possible.
The input AV port 1703 is used to identify video signal input. The configuration of the input AV port 1703 is the same as that of the output AV port 1702.
[0060]
Next, the structure of the data block stored in the data 1509 will be described with reference to FIG.
The data length of the data block is 192 bytes, and is composed of a 4-byte time stamp 1801 and an 188-byte MPEG2-TS packet 1802.
The time stamp 1801 stores a time stamp added by the time stamp adding unit 905A.
The MPEG2-TS packet 1802 stores the MPEG2-TS packet output from the video signal encoding unit 400A.
[0061]
In this embodiment, the value of the packet identification flag 1602 is 0 (transmission of information related to video data), the value of the format ID 1604 is 0x20 (MPEG2-TS), and the value of the data identification flag 1704 is 0 (video data).
[0062]
Next, an operation of generating time information that matches the time information output from the beacon timer unit 702A of the wireless master device 10A in the wireless slave device 10B will be described.
The beacon timer unit 702B of the wireless slave device 10B is generated by counting the clocks output from the clock generator 701B, and the time information of the wireless master device 10A included in the beacon periodically output by the wireless master device 10A. The time information periodically reset by is output (same as the conventional example). This time information is input to the PLL processing unit 904B.
[0063]
Here, both clocks output from the clock generation unit 701A of the wireless master device 10A and the clock generation unit 701B of the wireless slave device 10B cause an error due to a difference in accuracy.
When the time information is reset by the beacon, the time information may become discontinuous depending on the reset timing.
[0064]
The PLL processing unit 904B generates a new clock based on the input time information. The clock generated here is continuous time information, and since time information transmitted by a beacon from the wireless master device 10A is also input, it matches the clock output from the clock generator 701A of the wireless master device 10A. It will be.
The clock output from the PLL processing unit 904B is input to the time stamp timer unit 903B, and the time stamp timer unit 903B outputs the new time information by counting the input clocks. This time information also coincides with the time information output from the beacon timer unit 702A of the wireless master device 10A.
[0065]
Next, an operation in which the MPEG2-TS packet received by the wireless slave device 10B is output to the video signal decoding unit 500B in synchronization with the output timing of the video signal encoding unit 400A of the wireless master device 10A will be described.
The video signal transmitted from the wireless master device 10A is input to the antenna 30B of the wireless slave device 10B by the same operation as in the conventional example, and then output from the communication protocol processing unit 600B. The data output here is the MPEG2-TS packet with the time stamp added by the time stamp adding unit 905A on the transmission side.
[0066]
The data output from the communication protocol processing unit 600B is input to the reception data buffer unit 907B. The reception data buffer unit 907B outputs the received data to the time stamp extraction unit 901B.
The time stamp extraction unit 901B extracts a time stamp from the received data and outputs it to the time stamp comparison unit 902B.
The time stamp comparison unit 902B compares the time stamp of the received data with the time information output from the time stamp timer unit 903B, and outputs a control signal permitting output only to the received data buffer unit 907B when they match. .
[0067]
When the control signal is input, reception data buffer unit 907B outputs an MPEG2-TS packet obtained by removing the time stamp from the reception data to video signal decoding unit 500B.
[0068]
Next, resetting of the time stamp of the wireless slave device 10B (time information generated by the time stamp timer unit 903B of the wireless slave device 10B) will be described.
The time stamp comparison unit 902B outputs the time stamp extracted by the time stamp extraction unit 901B to the initial value setting unit 910B. The initial value setting unit 910B resets the time stamp of the wireless slave device 10B using this time stamp.
That is, by resetting the time information generated by the time stamp timer unit 903B using the time stamp of the current radio base unit 10A (the count value of the clock output from the PLL processing unit 904B), It is possible to synchronize the time stamp of the wireless slave device 10B.
[0069]
For example, assume that the time stamp of the wireless master device 10A is “1000”, the time required for communication between the wireless master device 10A and the wireless slave device 10B is “10”, and the time stamp of the wireless slave device 10B is “2000”. That is, the time stamps of the wireless master device 10A and the wireless slave device 10B are currently different between “1000” and “2000”.
[0070]
When the wireless slave device 10B receives data from the wireless master device 10A, the time stamps of the wireless master device 10A and the wireless slave device 10B should be counted as “1010” and “2010”, respectively. Here, it is assumed that the time stamp of the wireless slave device 10B is reset using the time stamp “1000” of the wireless master device 10A received by the wireless slave device 10B.
Then, if the wireless master device 10A is set to transmit data when the time stamp is “1015”, the time stamp of the wireless slave device 10B is “1000” when the time stamp of the wireless master device 10A is “1010”. When the wireless master device 10A is “1015”, the time stamp of the wireless slave device 10B is “1005”. That is, the data is transmitted from the wireless slave device 10B at the time “1015” after “10” has elapsed by the data delay time (communication time) from the wireless master device 10A to the wireless slave device 10B.
[0071]
If the time stamp of the wireless slave device 10B is not reset, the time stamp of the wireless slave device 10B when the time stamp of the wireless master device 10A is “1015” is “2015” and “1015”. Even if an instruction is given to transmit data at this time, the data is not transmitted. Therefore, it is necessary to match the time stamps of the wireless master device 10A and the wireless slave device 10B in advance.
Therefore, the time information output from the time stamp timer unit 903B matches the time information output from the beacon timer unit 702A of the wireless master device 10A.
[0072]
As described above, by outputting to the video signal decoding unit 500B based on the time stamp added to the received data, the timing of the MPEG2-TS packet input to the video signal decoding unit 500B is the video of the wireless master device 10A. This coincides with the output timing of the MPEG2-TS packet output by the signal encoding unit 400A.
[0073]
Example 2
FIG. 2 is a block diagram illustrating a configuration of the wireless transmission device according to the second embodiment.
In FIG. 2, the PLL processing unit 904A and the time stamp timer unit 903A of the wireless master device 10A constitute a second PLL unit.
[0074]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the wireless transmission apparatus (FIG. 1) of Example 1, or an equivalent part.
In the wireless transmission device according to the second embodiment, a time stamp timer unit 903A and a PLL processing unit 904A are newly added to the wireless master device 10A.
[0075]
The operation of the wireless transmission apparatus according to the second embodiment configured as described above will be described below with respect to operations different from the conventional example.
[0076]
First, the operation when the time stamp time information with higher time accuracy is generated from the time information output from the beacon timer unit 702A in the wireless master device 10A will be described. In a wireless transmission device compliant with IEEE 802.11, the accuracy of the time information output from the beacon timer unit 702A is 1 microsecond. On the other hand, the clock used in MPEG2-TS is 27 MHz, and the accuracy difference is large.
[0077]
In the wireless master device 10A, the PLL processing unit 904A is for generating a clock having a higher frequency than the time information output from the beacon timer unit 702A. Here, the PLL processing unit 904A generates a 27 MHz clock. The clock output from the PLL processing unit 904A is input to the time stamp timer unit 903A and outputs time information having an accuracy of 27 MHz to the time stamp adding unit 905A.
[0078]
The time stamp adding unit 905A adds the time information output from the time stamp timer unit 903A to the MPEG2-TS packet output from the video signal encoding unit 400A, and outputs it to the communication protocol processing unit 600A.
Thus, time information generated from the 27 MHz clock following the clock generated by the clock generation unit 701A is added to the MPEG2-TS packet and transmitted.
[0079]
Next, an operation in which the MPEG2-TS packet received by the wireless slave device 10B is output to the video signal decoding unit 500B in synchronization with the output timing of the video signal encoding unit 400A of the wireless master device 10A will be described.
The operation of the wireless slave device 10B is the same as that of the wireless slave device 10B of the first embodiment, but the clock generated by the PLL unit 904B is different (the clock frequency of the second embodiment is much higher than that of the first embodiment). .) Here, a clock having the same frequency as the clock generated by the PLL processing unit 904A of the wireless master device 10A is generated. This clock is generated so as to follow the time information of the beacon timer unit 702B as in the first embodiment.
[0080]
Accordingly, the time information output from the time stamp timer unit 903A of the wireless master device 10A and the time stamp timer unit 903B of the wireless slave device 10B coincide with each other, and MPEG2 input to the video signal decoding unit 500B of the wireless slave device 10B. The timing of the TS packet coincides with the output timing of the MPEG2-TS packet output from the video signal encoding unit 400A of the wireless master device 10A with the clock accuracy of 27 MHz (accuracy of about 0.037 microseconds).
[0081]
Example 3
FIG. 3 is a block diagram illustrating the configuration of the wireless transmission device according to the third embodiment.
In FIG. 3, an offset adding unit 906A of the radio cell station 10A indicates a first offset calculating unit, and a time stamp comparing unit 902A indicates a second time information comparing unit.
[0082]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIG. 1 or FIG. 2) of Example 1 or Example 2 or FIG.
In the wireless transmission device according to the third embodiment, a time stamp extraction unit 901A, a time stamp comparison unit 902A, and an offset addition unit 906A are newly added to the wireless master device 10A.
[0083]
The wireless transmission device according to the third embodiment configured as described above is characterized in that it has a function (offset addition) for correcting the time stamp added to the video signal by the wireless master device 10A with the time required for communication.
Hereinafter, the operation of the wireless transmission device according to the third embodiment will be described.
[0084]
First, data to which a time stamp is added is transmitted by the wireless master device 10A and received by the wireless slave device 10B via the wireless communication line. The frame analysis unit 705B of the wireless slave device 10B analyzes the received data. If the data is destined for the own device, the received data is output to the frame assembly unit 704B as it is, via the frame assembly unit 704B and the RF unit 800B. To send back to the wireless base unit 10A.
[0085]
Data originally sent back from the wireless slave device 10B and sent from the wireless master device 10A is input to the received data buffer unit 907A via the MAC processing unit 700A and the communication protocol processing unit 600A.
Reception data buffer unit 907A outputs the received data to time stamp extraction unit 901A. The time stamp extraction unit 901A extracts a time stamp from the received data and outputs it to the time stamp comparison unit 902A.
[0086]
The time stamp comparison unit 902A compares the time stamp of the received data with the time information output from the time stamp timer unit 903A. Thereby, it is possible to know the round trip time required for data transmission between the wireless master device 10A and the wireless slave device 10B. That is, the time stamp output from the time stamp timer unit 903A is current time information, and the time stamp output from the time stamp extraction unit 901A is an MPEG2-TS packet from the video signal encoding unit 400A of the wireless master device 10A. Therefore, the difference in time information between the time stamp timer unit 903A and the time stamp extraction unit 901A means the time required for data transmission / reception.
[0087]
Time stamp comparison section 902A outputs the comparison result (time information difference) to offset addition section 906A.
The offset adding unit 906A calculates an offset value based on the time information difference. The offset adding unit 906A generates a time stamp by correcting the time information output from the time stamp timer unit 903A with the calculated offset value, and outputs the time stamp to the time stamp adding unit 905A.
[0088]
The time stamp adding unit 905A adds the time stamp generated by the offset adding unit 906A to the MPEG2-TS packet and outputs it to the communication protocol processing unit 600A.
This data transmission / reception required time can be said to be one of effective data in the case of adding an offset to the time information (time stamp) output from the time stamp timer unit 903A in the wireless master device 10A.
[0089]
For example, it is assumed that the time stamps output by the time stamp timer unit 903A of the wireless master device 10A and the time stamp timer unit 903B of the wireless slave device 10B are “1015” and “1005”, respectively. At this time, the offset value “10” is added to the time stamp of the wireless master device 10A.
The reception data buffer unit 907B of the wireless slave device 10B outputs an MPEG2-TS packet when the time stamp of the wireless slave device 10B is “1015”.
[0090]
Here, if the time required for data transmission from the wireless master device 10A to the wireless slave device 10B is shorter than “10”, the wireless slave device is between the time stamps “1005” and “1015” of the wireless slave device 10B. Data is stored in the received data buffer unit 907B of 10B.
If the amount of data (total size) received by the wireless slave device 10B exceeds the buffer size of the received data buffer unit 907B until the time stamp of the wireless slave device 10B reaches “1015”, Buffer overflow occurs.
Therefore, it is necessary to appropriately adjust the offset value to an appropriate value instead of a fixed value by using the time required for data transmission / reception.
[0091]
Next, addition of offset using the data transmission / reception required time will be described.
It is assumed that the round-trip time required for data transmission between the wireless master device 10A and the wireless slave device 10B obtained by the wireless master device 10A by the time stamp comparison unit 902A is “10”. At this time, the time stamp comparison unit 902A outputs the value “10” to the offset addition unit 906A.
[0092]
The offset adding unit 906A calculates an offset value using this value. Here, since the one-way communication time (data transmission time from the wireless master device 10A to the wireless slave device 10B) is used as the offset value, for example, “5” obtained by dividing “10” by 2 is used as the offset value. The offset adding unit 906A adds the calculated offset value “5” to the time information (eg, “1005”) output from the time stamp timer unit 903A to generate the time stamp “1010”, and the time stamp adding unit 905A Output to.
[0093]
The time stamp adding unit 905A adds the time stamp “1010” generated by the offset adding unit 906A to the MPEG2-TS packet and outputs it to the communication protocol processing unit 600A.
The wireless slave device 10B extracts a time stamp from the received MPEG2-TS packet and compares it with the time information of the time stamp timer unit 903B of the wireless slave device 10B. The difference between the two at this time is obtained by subtracting the time required for data transmission from the offset value.
[0094]
In this manner, the timing at which the reception data buffer unit 907B outputs the reception data to the video signal decoding unit 500B can be appropriately controlled using the offset value generated by the wireless master device 10A.
This offset value is based on the time required for transmission between the wireless master device 10A and the wireless slave device 10B. Therefore, it is possible to appropriately control the period of time until the reception data is output by the reception data buffer unit 907B.
In the third embodiment, the wireless slave device 10B sends the received data back to the wireless master device 10A as it is. Since this method does not analyze the data contents in the wireless slave unit, the data processing burden on the microcomputer of the wireless slave unit is light. However, the amount of data sent back from the wireless slave device to the wireless master device increases. In another embodiment, the wireless slave unit extracts the time information and the packet ID code (identification information) of the packet data from the received data, and sends back only the information to the wireless master unit. As a result, the amount of data sent back from the wireless slave device to the wireless master device can be reduced. In yet another embodiment, the wireless slave unit extracts time information from the received data and sends back only the time information to the wireless master unit (the time information returned from the wireless slave unit is This is useful when you can correctly identify which packet data was attached to.)
[0095]
Example 4
FIG. 4 is a block diagram illustrating a configuration of the wireless transmission device according to the fourth embodiment.
In FIG. 4, an offset adding unit 906A of the wireless base device 10A indicates a first offset calculating unit. In the wireless slave device 10B, a reception data buffer unit 907B indicates a reception data buffer unit, and a reception data amount detection comparison unit 909B indicates a reception data size detection unit.
[0096]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the wireless transmission apparatus (FIGS. 1-3) of Example 1-Example 3 (FIGS. 1-3).
In the wireless transmission device according to the fourth embodiment, a reception data amount detection / comparison unit 909A is newly added to the wireless master device 10A, and a reception data buffer reference value storage unit 908B and a reception data amount detection comparison unit 909B are added to the wireless slave device 10B. In addition, an offset adding unit 906B is newly added.
[0097]
In the wireless transmission device according to the fourth embodiment configured as described above, the wireless master device 10A determines the offset value of the time information based on the amount of data stored in the reception data buffer unit 907B of the wireless slave device 10B. It is characterized in that the time stamp is corrected using the offset value.
The operation of the wireless transmission device according to the fourth embodiment will be described below.
[0098]
First, data received by the wireless slave device 10B is stored in the received data buffer unit 907B. The reception data amount detection / comparison unit 909B detects the total size of the data stored in the reception data buffer unit 907B. Further, the reference data size of the reception data buffer unit 907B stored in the data buffer reference value storage unit 908B is referred to, and the reference data size is compared with the detected reception data size. As a result of the comparison, if the difference between the two exceeds a predetermined value, the wireless slave device 10B sends the received data buffer information including the received data size and the reference data size via the offset adding unit 906B and the time stamp adding unit 905B. And transmitted to the wireless master device 10A.
[0099]
The wireless master device 10A stores the received data buffer information transmitted from the wireless slave device 10B in the received data buffer unit 907A. The reception data amount detection / comparison unit 909A extracts the reception data buffer information from the reception data buffer unit 907A and outputs it to the offset addition unit 906A.
The offset adding unit 906A calculates an offset value based on the received data buffer information (received data size, reference data size). The offset adding unit 906A corrects the time information output from the time stamp timer unit 903A with the calculated offset value, generates a time stamp, and outputs the time stamp to the time stamp adding unit 905A.
[0100]
For example, when the reception data size is larger than the reference data size, that is, in this case, the reception data amount of the wireless slave unit 10B increases with the passage of time from the data processing amount of the wireless slave unit 10B. Therefore, it is necessary to set the offset value small in order to prevent the reception data buffer unit 907B from overflowing with reception data.
[0101]
On the other hand, when the received data size is smaller than the reference data size, that is, in this case, the amount of data received by the wireless slave unit 10B is reduced with the passage of time from the data processing amount of the wireless slave unit 10B. There is no reception data from the reception data buffer unit 907B, and data cannot be output to the video signal decoding unit 500B.
[0102]
Therefore, the amount of data stored in the wireless slave device 10B is adjusted by adjusting the offset value based on the received data size and the reference data size received from the wireless slave device 10B and correcting the time stamp using the offset value. Can be controlled.
[0103]
Example 5
FIG. 5 is a block diagram illustrating a configuration of a wireless transmission device according to the fifth embodiment.
The same or corresponding parts as those of the wireless transmission devices (FIGS. 1 to 4) of the first to fourth embodiments are denoted by the same reference numerals.
[0104]
In the wireless transmission device according to the fifth embodiment configured as described above, the wireless slave device 10B obtains the offset value of the time information based on the amount of data stored in the reception data buffer unit 907B of the wireless slave device 10B. It has characteristics.
Hereinafter, the operation of the wireless transmission device according to the fifth embodiment will be described.
First, reception data received by the wireless slave device 10B is accumulated in the reception data buffer unit 907B. The reception data amount detection / comparison unit 909B detects the total size of the data stored in the reception data buffer unit 907B. Further, reference is made to the reference data size of the reception data buffer unit 907B stored in the data buffer reference value storage unit 908B, and information on this reference data size and the detected reception data size is output to the offset addition unit 906B.
[0105]
The offset adding unit 906B calculates an offset value based on this information and the time information output from the time stamp timer unit 903B, and outputs the offset value to the time stamp timer unit 903B.
The time stamp extraction unit 901B extracts a time stamp from the received data and outputs it to the time stamp comparison unit 902B.
[0106]
The time stamp comparison unit 902B compares the time stamp of the received data with the time stamp corrected using the adjusted offset output from the time stamp timer unit 903B, and controls to permit output only when the two match. The signal is output to the reception data buffer unit 907B.
When the control signal is input, reception data buffer unit 907B outputs an MPEG2-TS packet obtained by removing the time stamp from the reception data to video signal decoding unit 500B.
[0107]
Here, the offset adjustment will be described. For example, when the reception data size is larger than the reference data size, that is, when the reception data amount of the wireless slave unit 10B increases with the passage of time from the data processing amount of the wireless slave unit 10B, the reception data buffer unit In order to prevent 907B from overflowing with received data, it is necessary to set a small offset value.
[0108]
On the other hand, when the received data size is smaller than the reference data size, that is, when the received data amount of the wireless slave unit 10B is decreased with the passage of time from the data processing amount of the wireless slave unit 10B, the received data buffer No data is received from unit 907B, and data cannot be output to video signal decoding unit 500B. Therefore, by setting a large offset value, it is possible to control the amount of received data stored in the received data buffer unit 907B.
[0109]
Example 6
FIG. 6 is a block diagram illustrating a configuration of a wireless transmission device according to the sixth embodiment.
In FIG. 6, a reception error frequency detection unit 911B of the wireless slave device 10B indicates a reception error frequency detection unit.
[0110]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-5) of Example 1-Example 5 (FIGS. 1-5).
In the wireless transmission device according to the sixth embodiment, a reception error frequency detection unit 911B is newly added to the wireless slave device 10B.
[0111]
In the wireless transmission device according to the sixth embodiment configured as described above, the wireless slave device 10B sets the offset value of the time information based on the error frequency of the reception data detected by the reception error frequency detection unit 911B of the wireless slave device 10B. Characterized by the desired point.
The operation of the wireless transmission device according to the sixth embodiment will be described below.
[0112]
The reception data processing unit 706B of the wireless slave unit 10B detects the transmission error that occurs in the section of the wireless communication line, and when an error is detected, the reception error frequency detection unit 911B is notified.
The reception error frequency detection unit 911B detects the frequency of occurrence of transmission errors and outputs the detected frequency of occurrence of transmission errors to the offset addition unit 906B.
[0113]
The offset adding unit 906B calculates an offset value based on the transmission error occurrence frequency and the time information output from the time stamp timer unit 903B, and outputs the offset value to the time stamp timer unit 903B.
Thereafter, the operation until the MPEG2-TS packet is output to the video signal decoding unit 500B is the same as that of the fifth embodiment.
[0114]
Here, the offset adjustment will be described. For example, when the frequency of occurrence of transmission errors is high, the correct data has not been received, so the wireless slave device 10B requests retransmission to the wireless master device 10A. Meanwhile, since the reception data is sent from the reception data buffer unit 907B to the video signal decoding unit 500B in the wireless slave device 10B, the data stored in the reception data buffer unit 907B continues to decrease. If there is no data in the reception data buffer unit 907B, the video is interrupted. That is, when the amount of reception data stored in the reception data buffer unit 907B is small and the frequency of occurrence of transmission errors is high, the video is immediately interrupted. Therefore, it is necessary to increase the offset value and accumulate sufficient data in the reception data buffer unit 907B in advance.
[0115]
On the other hand, when the frequency of occurrence of transmission errors is low, correct data has been received, and the wireless slave device 10B does not request retransmission to the wireless master device 10A. In the wireless slave device 10B, since the reception data is sent from the reception data buffer unit 907B to the video signal decoding unit 500B, the amount of data stored in the reception data buffer unit 907B remains constant or continues to increase. become. If it continues to increase, the reception data overflows from the reception data buffer unit 907B.
[0116]
Further, if the processing is performed with the offset being too large, a large difference in processing time between the wireless master device 10A and the wireless slave device 10B is generated, resulting in an image with a reproduction delay. Therefore, in these cases, it is necessary to reduce the offset.
In this way, by adjusting the offset according to the frequency of occurrence of transmission errors in the wireless communication line, it is possible to prevent the occurrence of interrupted video or delay.
[0117]
Example 7
FIG. 7 is a block diagram illustrating a configuration of a wireless transmission device according to the seventh embodiment.
In FIG. 7, a reception field strength measurement unit 912B indicates a reception field strength measurement unit.
[0118]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-5) of Example 1-Example 5 (FIGS. 1-5).
In the wireless transmission device according to the seventh embodiment, a reception field strength measurement unit 912B is newly added to the wireless slave device 10B.
[0119]
In the wireless transmission device according to the seventh embodiment configured as described above, the wireless slave device 10B obtains an offset value of time information based on the received electric field strength value detected by the received electric field strength measurement unit 912B of the wireless slave device 10B. Characterized by points.
The operation of the wireless transmission device according to the seventh embodiment will be described below.
[0120]
The reception field strength measurement unit 912B measures the reception field strength in the section of the wireless communication line, and outputs the measured reception field strength value to the offset addition unit 906B.
The offset adding unit 906B calculates an offset value based on the received electric field strength value and the time information output from the time stamp timer unit 903B, and outputs the offset value to the time stamp timer unit 903B.
Thereafter, the operation until the MPEG2-TS packet is output to the video signal decoding unit 500B is the same as that of the fifth embodiment.
[0121]
Here, the offset adjustment will be described. For example, when the received electric field strength is weak, there is a possibility that data cannot be received correctly or the communication itself is likely to be interrupted. Therefore, the wireless slave device 10B frequently retransmits to the wireless master device 10A. It is assumed that it will require. Meanwhile, since the reception data is sent from the reception data buffer unit 907B to the video signal decoding unit 500B in the wireless slave device 10B, the data stored in the reception data buffer unit 907B continues to decrease. If there is no data in the reception data buffer unit 907B, the video is interrupted. That is, when the amount of received data stored in the received data buffer unit 907B is small, if a transmission error or the like occurs, the video is immediately interrupted. Therefore, it is necessary to increase the offset and accumulate sufficient data in the reception data buffer unit 907B in advance.
[0122]
On the other hand, when the received electric field strength is strong, the wireless communication line 10B is not interrupted in the middle and the data can be received relatively correctly. Therefore, the wireless slave unit 10B does not request the wireless master unit 10A to retransmit. . In the wireless slave device 10B, since the reception data is sent from the reception data buffer unit 907B to the video signal decoding unit 500B, the amount of data stored in the reception data buffer unit 907B remains constant or continues to increase. become. If it continues to increase, the reception data overflows from the reception data buffer unit 907B. Further, if the processing is performed with the offset being too large, a large difference in processing time between the wireless master device 10A and the wireless slave device 10B is generated, resulting in an image with a reproduction delay. Therefore, in these cases, it is necessary to reduce the offset.
As described above, by adjusting the offset according to the strength of the received electric field strength in the wireless communication line section, it is possible to prevent the occurrence of an interrupted video or delay.
[0123]
Example 8
FIG. 8 is a block diagram illustrating the configuration of the wireless transmission device according to the eighth embodiment.
In FIG. 8, a beacon generation unit 703A and a frame assembly unit 704A of the wireless master device 10A constitute a transmission cycle setting unit.
[0124]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-4) of Example 1- Example 4 (FIGS. 1-4).
In the wireless transmission device according to the eighth embodiment, a PLL lock detection unit 913A that detects a PLL lock is newly added to the wireless master device 10A.
[0125]
The wireless transmission device according to the eighth embodiment configured as described above is characterized in that the wireless master device 10A has a function of adjusting the beacon transmission cycle.
The operation of the wireless transmission device according to the eighth embodiment will be described below.
[0126]
First, in the wireless communication line, when the wireless master device 10A recognizes a new wireless slave device 10B or before performing stream transmission to the wireless slave device 10B, the PLL lock detection unit 913A performs a beacon in the wireless master device 10A. It instructs the generation unit 703A to shorten the beacon period.
Receiving the instruction, the beacon generation unit 703A transmits a beacon to the frame assembly unit 704A at short intervals, and data is transmitted in accordance with the beacon timing.
Normally, when the beacon period becomes long, it takes time to lock the PLL of the wireless slave device 10B, and it takes time until normal stream transmission can be performed.
Therefore, such a problem can be avoided by adjusting and shortening the PLL lock time.
[0127]
Example 9
FIG. 9 is a block diagram illustrating the configuration of the wireless transmission device according to the ninth embodiment.
In FIG. 9, a PLL lock detection unit 913B of the wireless slave device 10B is a PLL lock detection unit.
[0128]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-4) of Example 1- Example 4 (FIGS. 1-4).
In the wireless transmission device according to the ninth embodiment, a PLL lock detection unit 913B that detects a PLL lock is newly added to the wireless slave device 10B.
[0129]
The wireless transmission device according to the ninth embodiment configured as described above is characterized in that the wireless master device 10A has a function of adjusting the beacon transmission period based on the PLL lock information detected by the wireless slave device 10B. Have.
The operation of the wireless transmission device according to the ninth embodiment will be described below.
[0130]
First, when the wireless slave device 10B locks the PLL, the PLL lock detection unit 913B generates lock detection information. The generated lock detection information is transmitted to the wireless master device 10A via the communication protocol processing unit 600B. The PLL lock detection unit 913A of the wireless master device 10A instructs the beacon generation unit 703A to change the beacon period based on the lock detection information from the wireless slave device 10B.
Receiving the instruction, the beacon generation unit 703A transmits data at the timing of the changed transmission cycle via the frame assembly unit 704A.
In this way, by detecting the lock of the PLL of the wireless slave device 10B in advance and then transmitting the video signal, it is possible to avoid the problem that the wireless slave device 10B cannot normally receive the video signal.
[0131]
Example 10
FIG. 10 is a block diagram illustrating a configuration of the wireless transmission device according to the tenth embodiment.
In FIG. 10, a received electric field strength measuring unit 912B of the wireless slave device 10B is a received electric field strength measuring unit.
[0132]
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-4 and FIG. 7) of Example 1- Example 4 and Example 7, or FIG.
In the wireless transmission device according to the tenth embodiment, a reception field strength measurement unit 912A is newly added to the wireless master device 10A.
[0133]
The wireless transmission device according to the tenth embodiment configured as described above is characterized in that the wireless master device 10A has a function of adjusting the beacon transmission period based on the received electric field strength value measured by the wireless slave device 10B. Have.
The operation of the wireless transmission device according to the tenth embodiment will be described below.
First, the reception field strength measurement unit 912B of the wireless slave device 10B measures the reception field strength in the section of the wireless communication line. The measured received electric field strength value is transmitted to the wireless master device 10A via the communication protocol processing unit 600B. The received electric field strength measurement unit 912A of the wireless master device 10A instructs the beacon generator 703A to change the beacon period based on the received electric field strength value from the wireless slave device 10B.
[0134]
Here, the setting of the beacon period will be described. For example, when the received electric field strength is weak, there is a possibility that data cannot be received correctly because the communication state is bad, or the communication itself is likely to be interrupted. Therefore, the beacon signal itself may be missed and the PLL lock may not be achieved. Therefore, by shortening the beacon period, it is possible to reduce the number of times the beacon period is missed and to improve the PLL from being removed.
[0135]
On the other hand, when the received electric field strength is strong, the wireless communication line 10B is not interrupted in the middle and the data can be received relatively correctly. Therefore, the wireless slave unit 10B does not request the wireless master unit 10A to retransmit. . In the wireless slave device 10B, since the beacon is not missed and the PLL is locked, frequent beacon transmission conversely reduces the data transmission rate and consumes transmission energy. Therefore, when the received electric field strength is strong, the beacon period is set long. As a result, it is possible to solve these problems of reduction in transmission throughput and energy consumption.
[0136]
Example 11
FIG. 11 is a block diagram illustrating the configuration of the wireless transmission device according to the eleventh embodiment.
In FIG. 11, a reception error frequency detection unit 911B of the wireless slave device 10B indicates a reception error frequency detection unit.
In addition, the same code | symbol is attached | subjected about the part which is the same as that of the radio | wireless transmission apparatus (FIGS. 1-4, and FIG. 6) of Example 1- Example 4 and Example 6 (FIGS. 1-4).
In the wireless transmission device according to the eleventh embodiment, a reception error frequency detection unit 911A is newly added to the wireless master device 10A.
[0137]
The wireless transmission device according to the eleventh embodiment configured as described above is characterized in that the wireless master device 10A has a function capable of adjusting the beacon transmission cycle based on the reception error frequency detected by the wireless slave device 10B.
The operation of the wireless transmission device according to the eleventh embodiment will be described below.
The reception data processing unit 706B of the wireless slave unit 10B detects the transmission error that occurs in the section of the wireless communication line, and when an error is detected, the reception error frequency detection unit 911B is notified.
[0138]
The reception error frequency detection unit 911B detects the occurrence frequency of transmission errors and generates error occurrence frequency information. The generated error occurrence frequency information is transmitted to the wireless master device 10A via the communication protocol processing unit 600B. The reception error frequency detection unit 911A of the wireless master device 10A instructs the beacon generation unit 703A to change the beacon period based on the error occurrence frequency information from the wireless slave device 10B.
Receiving the instruction, the beacon generation unit 703A transmits data at the timing of the changed transmission cycle via the frame assembly unit 704A.
[0139]
As described above, when the error occurrence frequency information detected by the wireless slave device 10B is transmitted to the wireless master device 10A and the beacon period is adjusted based on the error occurrence frequency information, for example, when the occurrence frequency of transmission errors is high By shortening the beacon period, the number of missed beacon periods can be reduced and the PLL can be prevented from coming off.
On the other hand, when the frequency of occurrence of transmission errors is low, it is possible to solve these problems of reduction in transmission throughput and energy consumption by setting a longer beacon period.
[0140]
【The invention's effect】
The wireless transmission apparatus according to the present invention can reliably synchronize the transmission side and the reception side in stream transmission of video signals and the like, and thus can prevent video frames from dropping and reproduce video signals accurately.
[0141]
The wireless transmission device according to the present invention has a function of detecting a transmission time, and adjusts the timing of synchronization according to the transmission time. Therefore, the wireless transmission device is not easily affected by changes in radio wave propagation status and can accurately reproduce a video signal. .
[0142]
The radio transmission apparatus according to the present invention has a function of detecting the frequency of occurrence of transmission errors on the receiving side, and performs synchronization timing adjustment according to the frequency of occurrence of transmission errors, so that the influence of changes in the propagation state of the radio channel is affected. It is difficult to receive and can accurately reproduce video signals.
[0143]
The radio transmission apparatus according to the present invention has a function of measuring the received electric field strength on the receiving side, and adjusts the synchronization timing based on the measured received electric field strength value, so that it is affected by changes in the propagation state of the radio line. It is difficult to reproduce video signals accurately.
[0144]
Since the wireless transmission device according to the present invention can adjust the beacon period on the transmission side, it can shorten the time required for stream transmission to the reception side.
[0145]
In the wireless transmission device according to the present invention, since the transmission side can detect the lock of the PLL on the reception side and performs the stream transmission thereafter, the reception side can reliably receive the stream signal.
[0146]
The radio transmission apparatus according to the present invention can adjust the beacon period on the transmission side according to the received electric field strength value, and thus is not easily affected by a change in the propagation state of the radio line. Therefore, when the received electric field strength is weak, by shortening the beacon period, it is possible to reduce the number of times the beacon period is missed and to prevent the PLL from coming off. Further, when the received electric field strength is strong, the problem of the decrease in transmission throughput and the energy consumption can be solved by setting the beacon period longer.
[0147]
The radio transmission apparatus according to the present invention can adjust the beacon period on the transmission side according to the frequency of occurrence of transmission errors on the reception side, and thus is not easily affected by changes in the propagation state of the radio line. Therefore, when the frequency of occurrence of transmission errors is high, the beacon period can be shortened to reduce the number of times the beacon period is missed and to prevent the PLL from coming off. Further, when the frequency of occurrence of transmission errors is low, the problem of reduction in transmission throughput and energy consumption can be solved by setting the beacon period to be long.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a wireless transmission device according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a configuration of a wireless transmission device according to a second embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration of a wireless transmission device according to a third embodiment of the present invention.
FIG. 4 is a block diagram illustrating a configuration of a wireless transmission device according to a fourth embodiment of the present invention.
FIG. 5 is a block diagram illustrating a configuration of a wireless transmission device according to a fifth embodiment of the present invention.
FIG. 6 is a block diagram illustrating a configuration of a wireless transmission device according to a sixth embodiment of the present invention.
FIG. 7 is a block diagram illustrating a configuration of a wireless transmission device according to a seventh embodiment of the present invention.
FIG. 8 is a block diagram illustrating a configuration of a wireless transmission device according to an eighth embodiment of the present invention.
FIG. 9 is a block diagram illustrating a configuration of a wireless transmission device according to a ninth embodiment of the present invention.
FIG. 10 is a block diagram illustrating a configuration of a wireless transmission device according to a tenth embodiment of the present invention.
FIG. 11 is a block diagram illustrating a configuration of a wireless transmission device according to an eleventh embodiment of the present invention.
FIG. 12 is a block diagram illustrating a configuration of a conventional wireless transmission device.
FIG. 13 is a timing chart showing the timing of a signal transmitted on a wireless line.
FIG. 14 is a block diagram showing an internal configuration of a MAC processing unit.
FIG. 15 is a diagram showing a format of a data packet used in communication in the embodiment of the present invention.
FIG. 16 is a diagram showing the structure of an AV information header 1507;
FIG. 17 is a diagram illustrating the structure of an AV port header 1508;
FIG. 18 is a diagram illustrating a structure of a data block stored in data 1509;
[Explanation of symbols]
10A wireless master unit
10B wireless handset
30A, 30B antenna
400A, 400B Video signal encoding unit
500A, 500B Video signal decoding unit
600A, 600B communication protocol processor
700A, 700B MAC processing unit
701A, 701B Clock generator
702A, 702B Beacon timer section
703A, 703B beacon generator
704A, 704B Frame assembly part
705A, 705B Frame analysis unit
706A, 706B Received data processing unit
800A, 800B RF section
901A, 901B Time stamp extraction unit
902A, 902B Timestamp comparison unit
903A, 903B Time stamp timer
904A, 904B PLL processing unit
905A, 905B Time stamp adder
906A, 906B Offset addition part
907A, 907B Receive data buffer
908A Reception data buffer reference value storage unit
909A, 909B received data amount detection comparator
910B initial value setting part
911A, 911B reception error frequency detection unit
912A, 912B Received electric field strength measurement unit
913A, 913B PLL lock detector
1501 Wireless header
1502 MAC header
1503 Frame body
1504 FCS
1505 IP header
1506 UDP header
1507 AV information
1508 AV port header
1509 data
1601 Protocol version
1602 Packet identification flag
1603 Extended information flag
1604 Format ID
1605 Copyright management information
1606 Data block size
1607 Number of data blocks
1608 Extended information
1701, 1705 Reserve
1702 Output AV port
1703 Input AV port
1704 Data identification flag
1706 1394 flag
1707 port number
1801 timestamp
1802 MPEG2-TS packet

Claims (23)

A wireless master device that transmits video signals as packet data between a wireless master device and a wireless slave device connected by a wireless line,
A time information generating unit for generating first time information used for synchronizing the internal timer of the wireless master device and the internal timer of the wireless slave device ;
A time information transmitter that intermittently transmits a control signal including the first time information at a predetermined period;
A video signal encoding unit that encodes the video signal and outputs it as packet data;
The time information derived based on the first time information or the first time information when the packet data of the video signal from the video signal encoding unit is output, as a timestamp, packets of the video signal A time information adding unit to be added for each data ;
A packet data transmission unit for transmitting packet data of the video signal output from the time information addition unit;
A wireless master device comprising: A wireless slave device that receives packet data of a video signal transmitted between a wireless master device and a wireless slave device connected by a wireless line,
A control signal including first time information used for synchronization between the internal timer of the wireless master device and the internal timer of the wireless slave device, which is intermittently transmitted from the wireless master device at a predetermined cycle, is input. A first PLL unit that extracts the first time information from the control signal and generates second time information that reproduces the first time information;
A receiving unit for receiving packet data of a video signal to which a time stamp, which is time information derived based on the first time information or the first time information, is transmitted from the wireless master unit;
The time stamp added to the video signal is extracted, the extracted time stamp is compared with the second time information generated by the first PLL unit, and the video signal is determined according to the comparison result. A first time information comparison unit for controlling the output timing of the packet data of
A video signal decoding unit for inputting and decoding packet data of the video signal at an output timing controlled by the first time information comparison unit;
A wireless handset characterized by comprising: A second PLL unit that generates time information with higher accuracy than the first time information based on the first time information;
Radio cell station according to claim 1 wherein the time information adding unit, wherein the second PLL unit is the generated time information is added to the packet data before SL video signal. The wireless master device according to claim 1 or 3,
The wireless slave device according to claim 2,
A wireless transmission device. The wireless slave device according to claim 2, wherein at least the time stamp added to the packet data of the video signal is retransmitted to the wireless master device. A second time information comparing unit that compares the time stamp retransmitted from the wireless slave device and the first time information or the time information derived based on the first time information;
Time information obtained by calculating an offset value based on a comparison result of the second time information comparison unit and correcting the first time information or time information derived based on the first time information with the offset value. A first offset calculation unit for generating
Further comprising
The time information adding unit adds the time information generated by the first offset calculating unit to the packet data of the video signal to be transmitted as a time stamp .
The wireless master device according to claim 1. A wireless master device according to claim 6;
The wireless slave device according to claim 5,
A wireless transmission device. A reception data buffer that temporarily holds packet data of the video signal until it is output to the video signal decoding unit ;
A reception data size detector for detecting the received data size is the size of the packet data of the video signals stored in the reception data buffer unit,
Further comprising
Received data buffer information including at least one of the received data size detected by the received data size detector and a comparison result between the received data size and a preset reference data size is transmitted to the wireless master unit The wireless slave device according to claim 2, wherein: The received data size of the packet data of the video signal transmitted from the wireless slave device and temporarily held in the reception data buffer unit of the wireless slave device, the received data size, and a preset reference data size The offset value is calculated based on the received data buffer information including at least one of the comparison results of the first time information or the time information derived based on the first time information as the offset value. A first offset calculating unit for generating corrected time information;
The wireless master device according to claim 1. A wireless master device according to claim 9,
The wireless slave device according to claim 8,
A wireless transmission device. A reception data buffer unit that temporarily holds until packet data of the video signal is output;
A reception data size detection unit for detecting a reception data size of packet data of a video signal held in the reception data buffer unit;
An offset value is calculated based on reception data buffer information including at least one of the reception data size detected by the reception data size detection unit and a comparison result between the reception data size and a preset reference data size. A second offset calculating unit that
Further comprising
The first time information comparison unit compares time information obtained by correcting the second time information with the offset value and time information added to packet data of the video signal, and compares the time information. Controlling the output timing of the packet data of the video signal according to the result,
The wireless slave device according to claim 2, wherein: A reception error frequency detection unit that detects the frequency at which the received data has an error;
A second offset calculation unit that calculates an offset value based on the reception error frequency detected by the reception error frequency detection unit;
Further comprising
The first time information comparison unit compares time information obtained by correcting the second time information with the offset value and time information added to packet data of the video signal, and compares the time information. Controlling the output timing of the packet data of the video signal according to the result,
The wireless slave device according to claim 2, wherein: A reception field strength measurement unit for measuring a reception field strength value;
A second offset calculating unit that calculates an offset value based on the received field strength value measured by the received field strength measuring unit;
Further comprising
The first time information comparison unit compares time information obtained by correcting the second time information with the offset value and time information added to packet data of the video signal, and compares the time information. Controlling the output timing of the packet data of the video signal according to the result,
The wireless slave device according to claim 2, wherein:   The wireless master device according to claim 1, further comprising a transmission cycle setting unit that changes a transmission cycle of the time information transmission unit. A PLL lock detecting unit that detects that the first PLL unit is locked and generates PLL lock information indicating that the first PLL unit is locked;
The wireless slave device according to claim 2, wherein the PLL lock information is notified to the wireless master device.   The transmission cycle setting unit changes the transmission cycle of the time information transmission unit based on PLL lock information transmitted from the wireless slave unit and indicating that the first PLL unit is locked. 14. The wireless master device according to 14. A wireless master device according to claim 16,
The wireless slave device according to claim 15,
A wireless transmission device. A reception field strength measurement unit for measuring a reception field strength value;
The wireless slave device according to claim 2, wherein the received electric field strength value is transmitted to the wireless master device.   The wireless parent according to claim 14, wherein the transmission cycle setting unit changes a transmission cycle of the time information transmission unit based on a received electric field strength value of the wireless slave device transmitted from the wireless slave device. Machine. The wireless master device according to claim 19,
The wireless slave device according to claim 18,
A wireless transmission device. It further includes a reception error frequency detection unit that detects the frequency at which the received data causes an error,
The wireless slave device according to claim 2, wherein the reception error frequency detected by the reception error frequency detection unit is transmitted to the wireless master device.   15. The wireless master device according to claim 14, wherein the transmission cycle setting unit changes a transmission cycle of the time information transmission unit based on a reception error frequency of the wireless slave device transmitted from the wireless slave device. . A wireless master device according to claim 22,
The wireless slave device according to claim 21,
A wireless transmission device.

Images