JP2004304584A - Transmitter, receiver, transmitting method, receiving method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmitter, a receiver, a transmitting method, a receiving method and a program for efficiently transmitting/receiving data while performing the technique of time diversity. <P>SOLUTION: A GMSK transmitter 1 acquires sound data and digital data of a transmitting target, generates a data stream consisting of a series of DV packets including sound data piece and digital data piece, modulates it, and transmits it as a GMSK modulation wave. However, when there are no digital data to be transmitted, the time diversity is applied to the sound data by storing the sound data piece also in a position which should be occupied by the digital data piece in the DV packet. A GMSK receiver obtains the data stream by demodulating the GMSK modulation wave and performs time diversity reception by selecting a bit received at the point of time when a receiving level is the strongest when a plurality of the same sound data pieces are included in the data stream. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmitting device, a receiving device, a transmitting method, a receiving method, and a program for realizing time diversity.
[0002]
[Prior art]
As a method of digital communication, voice communication and data communication are simultaneously performed by separately assigning a part for including voice data and a part for including binary data other than voice to each communication frame forming a packet. There is a method of making it possible (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP-A-10-178614
[0004]
On the other hand, in digital communication, a time diversity technique is used to compensate for deterioration in communication quality due to fading. Time diversity is a technique in which the same data is repeatedly transmitted a plurality of times, and a receiver or the like that receives the same data uses the same data transmitted a plurality of times with the highest reception level ( For example, see Patent Document 2).
[0005]
[Patent Document 2]
International Publication No. WO95 / 24786 pamphlet
[0006]
The time diversity technique has advantages over the spatial diversity technique in that it is not necessary to prepare two receivers or to perform a complicated phase shift.
[0007]
[Problems to be solved by the invention]
However, in the above-described digital communication method in which the voice data portion and the non-voice data portion are provided in each packet, when only the voice communication is performed and the data communication is not performed, the data of the packet other than the voice is not transmitted. Since partless data such as pseudo data is stored in the portion, communication between them is wasted.
In addition, when applying the time diversity method to such a digital communication method, it is necessary to transmit the same packet a plurality of times, and the transmission efficiency is deteriorated accordingly.
[0008]
The present invention has been made in view of the above situation, and has as its object to provide a transmission device, a reception device, a transmission method, a reception method, and a program for efficiently transmitting and receiving data while performing a time diversity technique.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, a transmitting device according to a first aspect of the present invention includes:
A transmitting apparatus for transmitting a packet including a first portion for storing a first type of data and a second portion for storing a second type of data,
Transmission mode determining means for determining whether to transmit the second type of data;
When the transmission mode determining means determines that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the packet or another packet. Packet storage means for further storing in the second part of
Packet sending means for sending out a packet storing the first type of data.
It is characterized by the following.
[0010]
According to such a transmission device, when the second type of data is not transmitted, it is possible to perform time diversity on the first type of data using the second portion of the packet. Therefore, it is not necessary to transmit the same packet a plurality of times, and time diversity is efficiently performed on the first type of data as a whole.
[0011]
When the transmission mode determining means determines that the second type of data is not to be transmitted, the packet storing means stores the first type of data in the first portion of the packet, and stores the first type of data. If the data is further stored in the second portion of the packet other than the packet, the same first type of data is transmitted at a sufficient time interval, so that the effect of the time diversity can be sufficiently obtained.
[0012]
The transmission mode determining means obtains, for example, information specifying whether to transmit the second type of data from the outside, and determines whether to transmit the transmission target data in accordance with the specification by the information. You may do so. With such a configuration, whether or not to perform time diversity can be determined by supplying information from the outside.
[0013]
The transmission mode determining means determines, for example, whether or not a second type of data is externally supplied to the packet storage means, and when determining that the second type of data is supplied, determines that the transmission target data is to be transmitted. However, when it is determined that the data to be transmitted is not supplied, it may be determined that the transmission target data is not transmitted. With such a configuration, whether to perform time diversity is automatically determined based on the presence or absence of the second type of data.
[0014]
For example, when the transmission mode determining unit determines that the second type of data is not to be transmitted, the packet storing unit stores or adds control data indicating that time diversity has been applied to the first type of data to the packet. You may make it.
[0015]
Further, a receiving apparatus according to a second aspect of the present invention includes:
A receiving apparatus for receiving a packet including a first part to store a first type of data and a second part to store a second type of data,
Packet receiving means for receiving one or more packets and specifying the level of the reception level at the time of receiving each part of the packets;
Transmission mode determining means for determining whether or not the packet received by the packet receiving means includes the second type of data;
When the transmission mode determining unit determines that the packet received by the packet receiving unit does not include the second type of data, the transmission mode determining unit specifies a plurality of first type data identical to each other included in the packet, Data selection means for selecting and outputting the part having the higher reception level from among the common parts of the specified first type of data,
It is characterized by the following.
[0016]
According to such a receiving apparatus, even when a packet in which the first type of data is stored for time diversity at a location where the second type of data is to be stored is received, the first type of data is also stored. Time diversity reception can be performed normally for the type of data. Therefore, time diversity is performed while the transmission efficiency of the first type of data is kept high.
[0017]
The transmission mode determining means detects, for example, whether or not control data indicating that time diversity has been applied to the first type of data is stored or added to the packet received by the packet receiving means, Based on the result of the detection, it may be determined whether or not the packet includes the second type of data.
[0018]
Further, the transmission method according to the third aspect of the present invention includes:
A transmission method for transmitting a packet including a first portion to store a first type of data and a second portion to store a second type of data,
Determining whether to transmit the second type of data,
When it is determined that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the second portion of the packet or another packet. Also stored in
Sending a packet in which the first type of data is stored;
It is characterized by the following.
[0019]
According to such a transmission method, when the second type of data is not transmitted, it is possible to perform time diversity on the first type of data using the second portion of the packet. Therefore, it is not necessary to transmit the same packet a plurality of times, and time diversity is efficiently performed on the first type of data as a whole.
[0020]
Further, a receiving method according to a fourth aspect of the present invention includes:
A receiving method for receiving a packet including a first portion to store a first type of data and a second portion to store a second type of data,
Receiving one or more packets, specifying the level of the reception level at the time of receiving each part of the packet,
Determine whether the received packet contains the second type of data,
When it is determined that the received packet does not include the second type of data, a plurality of first type data identical to each other included in the packet are identified, and each of the identified first type data is identified. Select and output the part with the higher reception level from the common parts of
It is characterized by the following.
[0021]
According to such a receiving method, even when a packet in which the first type of data is stored for time diversity at a location where the second type of data is to be stored is received, the first type of data is also stored. Time diversity reception can be performed normally for the type of data. Therefore, time diversity is performed while the transmission efficiency of the first type of data is kept high.
[0022]
Further, a program according to a fifth aspect of the present invention includes:
A program for causing a computer to function as a transmitting device that sends out a packet including a first portion to store a first type of data and a second portion to store a second type of data, The computer
Transmission mode determining means for determining whether to transmit the second type of data;
When the transmission mode determining means determines that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the packet or another packet. Packet storage means for further storing in the second part of
Packet sending means for sending a packet storing the first type of data;
It is characterized in that it is intended to function as
[0023]
According to the computer that executes such a program, when the second type of data is not transmitted, it is possible to perform time diversity on the first type of data using the second portion of the packet. . Therefore, it is not necessary to transmit the same packet a plurality of times, and time diversity is efficiently performed on the first type of data as a whole.
[0024]
Further, a program according to a sixth aspect of the present invention includes:
A program for causing a computer to function as a receiving device that receives a packet including a first portion to store a first type of data and a second portion to store a second type of data, The computer
Packet receiving means for receiving one or more packets and specifying the level of the reception level at the time of receiving each part of the packets;
Transmission mode determining means for determining whether or not the packet received by the packet receiving means includes the second type of data;
When the transmission mode determining unit determines that the packet received by the packet receiving unit does not include the second type of data, the transmission mode determining unit specifies a plurality of first type data identical to each other included in the packet, Data selecting means for selecting and outputting the portion having the higher reception level from among the common portions of the identified first type data,
It is characterized in that it is intended to function as
[0025]
According to the computer that executes such a program, even when a packet in which the first type of data is stored for time diversity at a location where the second type of data is to be stored is received, Time diversity reception can be performed normally for the first type of data. Therefore, time diversity is performed while the transmission efficiency of the first type of data is kept high.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a time diversity apparatus and a time diversity method according to an embodiment of the present invention will be described using a GMSK (Gaussian filtered Minimum Shift Keying) transmitter and a GMSK receiver as examples.
[0027]
(GMSK transmitter)
FIG. 1 shows an example of a configuration of a GMSK transmitter 1 according to an embodiment of the present invention.
As shown, the GMSK transmitter 1 includes a data input unit 11, a voice input unit 12, a voice compression unit 13, a pseudo data storage unit 14, a selection control unit 15, a data selection unit 16, a packet synthesis unit It comprises a unit 17, a modulating unit 18, and a modulated wave output unit 19.
[0028]
The data input unit 11 includes, for example, a serial interface circuit such as an RS-232C interface circuit or a USB (Universal Serial Bus) interface circuit. The data input unit 11 continuously acquires data (hereinafter, referred to as digital data) other than audio data, which is data to be transmitted in the form of a GMSK modulated wave, from the outside, and continuously acquires the data to the data selection unit 16. Supply.
[0029]
The audio input unit 12 includes, for example, a microphone, an AF (Audio Frequency) amplifier, etc., collects audio and converts it into an audio signal, amplifies the audio signal, and amplifies the audio signal to the audio compression unit 13. And supply continuously.
[0030]
The audio compression unit 13 includes, for example, an A / D (Analog-to-Digital) converter, a processor such as a CPU (Central Processing Unit) and a DSP (Digital Signal Processor), and a RAM that stores a program executed by the processor. (Random Access Memory), a memory such as a hard disk device, or a dedicated electronic circuit.
[0031]
The audio compression unit 13 converts the audio signal supplied from the audio input unit 12 into digital audio data, and subjects the audio data to data compression using, for example, an AMBE (Advanced Multi-Band Excitation) technique. Then, audio data fragments are generated by dividing the obtained compressed audio data every 48 bits, and a sequence of these audio data fragments is continuously transmitted from the top to the data selection unit 16 and the packet synthesis unit 17. And supply.
[0032]
The pseudo data storage unit 14 is configured by a nonvolatile memory such as a ROM (Read Only Memory), and stores pseudo data, which is data stored instead of digital data in a DV (Digital Voice) packet described later. The pseudo data is supplied to the data selection unit 16 according to the access of the data selection unit 16. In the following, it is assumed that the data amount of the pseudo data is 48 bits.
[0033]
Each of the selection control unit 15, the data selection unit 16, and the packet synthesis unit 17 is configured by, for example, a processor and a memory that stores a program executed by the processor, or is configured by a dedicated electronic circuit. Further, the selection control unit 15 further includes an input device such as a touch panel, and when an operator operates the input device, acquires information according to the operation.
[0034]
Note that one processor may perform at least two of the functions of the audio compression unit 13, the selection control unit 15, the data selection unit 16, and the packet synthesis unit 17. In addition, one memory device performs the function of the memory of at least two of the audio compression unit 13, the pseudo data storage unit 14, the selection control unit 15, the data selection unit 16, and the packet synthesis unit 17. You may.
[0035]
The selection control unit 15 acquires information (transmission mode designation information) for specifying whether to manually determine or automatically determine the ON / OFF of the time diversity according to the operation of the operator, and selects the transmission mode designation information for data selection. To the unit 16. Further, the selection control unit 15 acquires information instructing to turn on the time diversity or information instructing to turn off the time diversity, and supplies this information to the data selecting unit 16.
[0036]
Each time the selection control unit 15 supplies the transmission mode designation information, the data selection unit 16 acquires the transmission mode designation information, and the transmission mode designation information is used for manually determining the ON / OFF of the time diversity or for automatically determining the time diversity. Determine which one is specified.
[0037]
If the data selection unit 16 determines that manual determination of ON / OFF of the time diversity has been designated, the following (A1) to (A3) until new transmission mode designation information is supplied. The digital data is processed as shown in FIG.
[0038]
(A1) That is, the data selection unit 16 waits for the information for instructing to turn on the time diversity or the information to instruct to turn off the time diversity to be supplied from the selection control unit 15, and when the information is supplied, the supplied information becomes , To determine whether time diversity is on or off. Then, if it is determined that the instruction is OFF, the following processes (A2-A) and (A3) are performed until the next information for instructing ON or OFF (or new transmission mode designation information) is supplied. Do. When it is determined that the instruction is ON, the following processes (A2-B) and (A3) are performed until the next information for instructing ON or OFF (or new transmission mode designation information) is supplied.
[0039]
(A2-A) That is, when an instruction to turn off the time diversity is given, the pseudo data storage unit 14 is accessed to read out and temporarily store the pseudo data, while the digital data continuously supplied from the data input unit 11 is stored. Get data. Then, by supplying the obtained digital data to the packet synthesizing unit 17 in units of 48 bits from the head, a column of 48-bit digital data pieces is sequentially generated from the head of the column. However, during a period in which digital data is not supplied, pseudo data is added to the end of a column of digital data pieces by supplying pseudo data to the packet combining unit 17 instead of generating digital data pieces. .
[0040]
(A2-B) On the other hand, when the time diversity is instructed to be turned on, a sequence of audio data pieces continuously supplied from the audio compression unit 13 is acquired. Then, the first audio data fragment of the acquired column is temporarily stored until a certain delay time elapses, and then supplied to the packet synthesizing unit 17, and further subsequent audio data fragments are sequentially supplied to the packet synthesizing unit 17. Thus, a sequence of delayed audio data is generated.
[0041]
(A3) However, the data selection unit 16 inserts a synchronization frame having predetermined content into a sequence of digital data pieces (and / or pseudo data) sequentially generated or a row of delayed audio data pieces. Accordingly, the (20 · n) -th element (where n is an integer of 1 or more) from the beginning of the column of the digital data fragment is a digital data fragment generated by (A2-A) or (A2-B), Instead of pseudo data or audio data, a synchronous frame is used. Further, control data indicating the position of the head of the column of the delayed audio data fragment is stored in the digital data fragment located immediately before the beginning of the column of the delayed audio data fragment. The control data indicating the position of the end of the row of the delayed voice data piece is stored in the digital data piece located immediately after the end of the row of the data stream.
[0042]
On the other hand, when the data selection unit 16 determines that the automatic determination of the time diversity ON / OFF is specified, the data selection unit 16 performs the following (B1) to (B3) until new transmission mode specification information is supplied. The digital data is processed as shown in FIG.
[0043]
(B1) That is, when the automatic discrimination is instructed, the data selection unit 16 acquires the digital data continuously supplied from the data input unit 11 and the audio data continuously supplied from the audio compression unit 13. Also get a column of data pieces. Then, by dividing the obtained digital data every 48 bits from the top, a column of 48-bit digital data pieces is sequentially generated from the top of the column. However, during a period in which digital data is not supplied, instead of generating a digital data fragment, the audio data fragment supplied after the point in time that is delayed by the above-described delay time from the beginning of the period is referred to as a column of the digital data fragment. It shall be added sequentially to the end. In order to enable the addition of the audio data fragment, the data selection unit 16 temporarily stores the latest audio data fragment acquired from the audio compression unit 13 for the delay time described above. It shall be.
[0044]
(B2) However, the data selection unit 16 inserts a synchronization frame having a predetermined content into the sequence of the digital data pieces (and / or audio data pieces) that are sequentially generated, so that the beginning of the sequence of the digital data pieces is obtained. The (20 · n) -th element is a synchronous frame, not the digital data piece or audio data piece generated in (B1). Further, control data indicating the position of the head of the column of the delayed audio data fragment is stored in the digital data fragment located immediately before the beginning of the column of the delayed audio data fragment. The control data indicating the position of the end of the row of the delayed voice data piece is stored in the digital data piece located immediately after the end of the row of the data stream.
[0045]
The packet synthesizing unit 17 is supplied with a row of audio data pieces supplied by the audio compression unit 13 and a row of digital data pieces supplied by the data selection unit 16 (however, may include pseudo data or audio data pieces). Using the supplied data, the following operations (a) to (g) are performed to generate the data stream shown in FIG. 2 or FIG.
[0046]
That is, the packet combining unit 17
(A) First, bit synchronization data of a predetermined content of 64 bits to be added to the head of the bit stream is transmitted to the modulation unit 18,
(B) Next, 15-bit frame synchronization data having a predetermined content is transmitted to the modulation unit 18, and
(C) Next, 272-bit header information including information for identifying the bit stream is transmitted to the modulation unit 18, and
(D) Next, the first one of the unsent audio data pieces supplied by the audio compression unit 13 is transmitted to the modulation unit 18,
(E) Next, the first data fragment (digital data fragment, pseudo data, audio data, or synchronization frame) supplied by the data selection unit 16 that has not been transmitted is transmitted to the modulation unit 18. Send out.
(G) Then, the above operations (d) and (e) are alternately repeated.
[0047]
When the packet combiner 17 performs the operations (a) to (g), the data stream shown in FIG. 2 or 3 is transmitted from the packet combiner 17 to the modulator 18.
[0048]
FIG. 2 shows a case where time diversity is not performed, and the 39th audio data fragment (indicated as “audio data # 39” in FIGS. 2 and 3) supplied by the audio compression unit 13 is data selected. From the point in time when the data is supplied to the section 16 to the point in time when the 58th audio data fragment (indicated as “audio data # 58” in FIGS. 2 and 3) supplied by the audio compression section 13 is supplied to the data selection section 16 9 illustrates a case where digital data is not supplied to the data selection unit 16. As shown in FIGS. 2 and 3, the x-th audio data fragment (x is an arbitrary integer equal to or greater than 1) supplied by the audio compression unit 13 and the subsequent data supplied by the data selection unit 16 The pieces together form the xth DV packet.
[0049]
On the other hand, FIG. 3 shows a case where time diversity is performed, in which digital data is supplied from the time when the 39th audio data fragment supplied by the audio compression unit 13 is supplied to the time when the 58th audio data fragment is supplied. This is an example of a case where the data is not supplied to the data selection unit 16 (or the digital data is not acquired by the data selection unit 16), and the delay time corresponds to the time for transmitting three data pieces.
[0050]
If the delay time is too short, the interval between the same two audio data pieces in one data stream becomes too narrow, and these two audio data pieces of the GMSK modulated wave transmitted by the GMSK transmitter 1 are transmitted. It is highly likely that the difference between the electric field intensities of the two parts representing the above does not become sufficiently large at the receiving point, and the effect of time diversity cannot be sufficiently obtained. Therefore, the delay time needs to be a sufficiently large value.
[0051]
The modulation unit 18 is configured by a GMSK modulation circuit and the like, performs GMSK modulation on the data stream transmitted by the packet synthesis unit 17, and supplies the obtained GMSK modulation wave to the modulation wave output unit 19.
[0052]
The modulation wave output unit 19 includes an RF (Radio Frequency) amplifier circuit, an antenna, and the like, amplifies the GMSK modulation wave supplied from the modulation unit 18, and radiates it as an electromagnetic wave.
[0053]
According to the GMSK transmitter 1 described above, when there is no digital data to be transmitted using the DV packet, a portion to be occupied by the digital data is effectively used for transmitting audio data.
[0054]
(GMSK receiver)
FIG. 4 shows an example of a configuration of the GMSK receiver 2 according to the embodiment of the present invention.
As shown, the GMSK receiver 2 includes a modulation wave input unit 21, a level recording unit 22, a demodulation unit 23, a data separation unit 24, a switching control unit 25, a data output switching unit 26, -It is composed of a synthesizing unit 27, an audio expanding unit 28, and an audio reproducing unit 29.
[0055]
The modulation wave input unit 21 is configured by an antenna, an RF amplifier, and the like. The modulation wave input unit 21 receives and amplifies the GMSK modulation wave radiated by the GMSK transmitter 1, and supplies the GMSK modulation wave to the level recording unit 22 and the demodulation unit 23.
[0056]
The level recording unit 22 includes a smoothing circuit, an A / D converter, and the like. The level recording unit 22 generates digital data representing the amplitude of the GMSK modulated wave supplied from the modulated wave input unit 21, and converts the data into a GMSK. The modulated signal is supplied to the data selection / synthesis unit 27 as RSSI (Received Signal Strength Indicator) data representing the magnitude of the reception level of the modulated wave.
[0057]
The demodulation unit 23 includes a GMSK demodulation circuit and the like, and demodulates the GMSK modulation wave supplied from the modulation wave input unit 21 to restore the data stream generated by the packet synthesis unit 17 of the GMSK transmitter 1. . Then, the obtained data stream is sequentially supplied to the data separation unit 24 from the head.
[0058]
Each of the data separation unit 24, the switching control unit 25, the data output switching unit 26, the data selection / synthesizing unit 27, and the audio decompression unit 28 includes, for example, a processor and a memory that stores a program executed by the processor. It is composed of a dedicated electronic circuit.
In addition, the switching control unit 25 further includes an input device such as a touch panel, and when the operator operates the input device, acquires information according to the operation.
In addition, the data output switching unit 26 further includes a serial interface circuit such as an RS-232C interface circuit or a USB interface circuit.
[0059]
Note that one processor may perform at least two of the functions of the data separation unit 24, the switching control unit 25, the data output switching unit 26, the data selection / synthesis unit 27, and the audio decompression unit 28. . In addition, one memory device performs the function of the memory of any two or more of the data separation unit 24, the switching control unit 25, the data output switching unit 26, the data selection / synthesis unit 27, and the audio decompression unit 28. You may do so.
[0060]
The data separation unit 24 separates the sequence of the audio data fragments generated by the audio compression unit 13 of the GMSK transmitter 1 from the data stream supplied from the demodulation unit 23 and the sequence of the data fragments output by the data selection unit 16. I do. (Note that the audio data fragment generated by the audio compression unit 13 may be distinguished from the data fragment output by the data selection unit 16 based on the positional relationship with the synchronization frame, etc.) The sequence of the audio data pieces thus supplied is supplied to the data selection / synthesis unit 27, and the sequence of the data fragments output by the data selection unit 16 is supplied to the data output switching unit 26.
[0061]
The switching control unit 25 obtains information (reception mode designation information) for designating whether to manually switch the availability of time diversity reception or to perform automatic determination according to the operation of the operator, and switches the reception mode designation information to data output switching. To the unit 26. In addition, the switching control unit 25 acquires information instructing to turn on the time diversity reception or information instructing to turn off the time diversity reception, and supplies this information to the data output switching unit 26.
[0062]
The data output switching unit 26 obtains the reception mode designation information every time the switching control unit 25 supplies the reception mode designation information, and automatically determines whether the reception mode designation information manually switches the availability of time diversity reception. Is determined.
[0063]
When it is determined that the manual switching of the time diversity is designated, the data output switching unit 26 controls the switching control unit 25 to turn on or off the time diversity reception until new reception mode designation information is supplied. If information for instructing turning off is supplied, it is accepted. If the received information indicates that the time diversity reception is to be turned on, all the columns of the data pieces supplied from the data separation unit 24 are supplied to the data selection / combination unit 27. On the other hand, if it is an instruction to turn off the time diversity reception, the entire column of the data pieces supplied from the data separation unit 24 is output to the outside via its own serial interface circuit.
[0064]
On the other hand, if it is determined that the automatic determination is performed, the data output switching unit 26 outputs the data fragment supplied from the data separation unit 24 until the new reception mode specification information is supplied. Whether it is a data piece (whether or not the received GMSK modulated wave is time-diversified) is determined based on control data and the like included in these data pieces. Then, the data piece determined to be the voice data piece is supplied to the data selection / synthesis unit 27 with information for identifying the order of the voice data piece, and is supplied to the data selection / synthesis unit 27. The data piece determined to be the data piece is output to the outside.
[0065]
The data selection / synthesis unit 27 obtains the sequence of the audio data pieces supplied from the data separation unit 24, and also obtains the data pieces when supplied from the data output switching unit 26. Further, it also acquires the RSSI data supplied from the level recording unit 22. Then, time diversity reception is performed using the acquired data.
[0066]
That is, each time the data separating / synthesizing unit 27 newly supplies an audio data fragment from the data separating unit 24, the data selecting / synthesizing unit 27 outputs the same audio data fragment as this audio data fragment to the data supplied from the data output switching unit 26 later. Identify from the pieces. Then, with respect to these two identical voice data pieces, of the bits of the same digit, the one having the higher reception level of the portion indicating the bit in the original GMSK modulated wave is determined based on the value of the RSSI data. select.
[0067]
Then, when the receiving level of the GMSK modulated wave at the time when all the 48 bits of these two audio data pieces are received is selected, the selected 48 bits are set to the same as the original digits. , A single 48-bit audio data piece is synthesized. Then, the synthesized audio data fragment (that is, the audio data fragment received by the time diversity) is supplied to the audio decompression unit 28.
[0068]
Therefore, for example, in the case where the data stream has the structure shown in FIG. 3, if time diversity reception is performed on the audio data fragment # 38, the audio data fragment # 38 in the first half of the DV packet # 38 is subjected to data separation. When supplied from the unit 24, the audio data fragment # 38 is temporarily stored, and thereafter, it is checked whether the data fragment supplied from the data output switching unit 26 includes the audio data fragment # 38.
[0069]
When the latter half of the DV packet # 42 (that is, the audio data fragment # 38) is supplied from the data output switching unit 26, it is detected that the audio data fragment # 38 has been acquired, and this audio data fragment # 38, For the audio data fragment # 38 previously obtained from the data separation unit 24, the bit having the same digit and having the higher reception level of the corresponding portion of the GMSK modulated wave is selected based on the RSSI data.
[0070]
That is, as shown in FIG. 5, for example, the value of the RSSI data indicating the reception level of the GMSK modulated wave in the k-th (k is an integer of 1 to 48) bit of the previously acquired audio data piece # 38 is Assume that the value of the RSSI data indicating the reception level of the GMSK modulated wave at the time when the portion corresponding to the k-th bit of the voice data piece # 38 acquired later is “a”. b ". In this case, the k-th bit of the voice data fragment # 38 acquired later is selected as the k-th bit of the voice data fragment received by the time diversity.
[0071]
When 48 bits are selected using the two pieces of audio data # 38, an audio data piece # 38 that has been time-diversity-received is generated using these bits and supplied to the audio decompression unit 28. .
[0072]
The data selecting / synthesizing unit 27 performs the above-described operation each time a voice data piece is newly supplied from the data separating unit 24, so that the voice decompressing unit 28 is supplied with the time-diversity-received voice data sequence. Is done. This sequence of audio data pieces corresponds to the audio data after compression.
[0073]
The audio decompression unit 28 obtains a sequence of the audio data that has been time-diversity-received from the data selection / synthesis unit 27, and decompresses the audio data represented by the sequence to decompress the audio data. . Then, the expanded audio data is supplied to the audio reproducing unit 29.
[0074]
The audio reproducing unit 29 is configured by a D / A (Digital-to-Analog) converter, an AF amplifier, a speaker, and the like, and converts the audio data supplied from the audio expanding unit 28 into an analog audio signal. , Amplifies the obtained audio signal and reproduces the audio represented by the audio signal.
[0075]
By performing the operations described above, the GMSK receiver 2 restores the voice represented by the GMSK modulated wave from the GMSK modulated wave to which the GMSK transmitter 1 has performed time diversity while avoiding deterioration of communication quality due to fading. .
[0076]
The configurations of the GMSK transmitter 1 and the GMSK receiver 2 are not limited to those described above.
For example, the configuration of the data stream represented by the GMSK modulated wave is not limited to the above, and for example, the data length of the bit synchronization frame, the frame synchronization data, the header information, the audio data fragment, the digital data fragment or the pseudo data, or the synchronization frame is Arbitrary, and the interval between synchronization frames is also arbitrary. The order of arrangement of the audio data pieces and the digital data pieces in the DV packet is also arbitrary.
In addition, instead of performing time diversity on audio data, time diversity may be performed on digital data.
[0077]
The modulation format in which the GMSK transmitter 1 modulates the data stream does not need to be GMSK, and may be, for example, PSK (Phase Shift Keying) modulation or any other modulation format. However, the demodulation unit 23 of the GMSK receiver 2 is configured by a demodulation circuit or the like that can demodulate the modulated wave generated by the GMSK transmitter 1.
[0078]
Further, the method of compressing the audio data by the GMSK transmitter 1 does not need to be AMBE, and may be, for example, an IMBE (Improved Multi-Band Excitation) method or any other method. However, the audio decompression unit 28 of the GMSK receiver 2 is configured to be able to demodulate the audio data compressed by the method used by the GMSK transmitter 1.
[0079]
Further, the GMSK transmitter 1 may transmit the GMSK modulated wave to the wired line, and the GMSK receiver 2 may acquire the GMSK modulated wave from the wired line.
The GMSK transmitter 1 does not need to include the pseudo data storage unit 14. In this case, the data selection unit 16 may generate and use the pseudo data one by one.
[0080]
Further, the GMSK receiver 2 selects, instead of selecting the bit of the same digit of the two identical audio data pieces having the higher reception level of the corresponding part of the GMSK modulated wave, these two audio data pieces An average value or a sum of the reception levels of the corresponding portion of the GMSK modulated wave is obtained for a bit group belonging to a predetermined range of digits, and the bit group having the larger average value or the sum is combined with the audio data fragment ( It may be selected as a bit group that constitutes a time diversity received audio data piece).
[0081]
Moreover, transmission mode information indicating whether or not time diversity has been applied to the data stream may be included in the header information. In this case, for example, the data selection unit 16 supplies the data fragment supplied to the packet synthesis unit 17 with the time diversity processing (that is, the data fragment excluding the synchronization frame is the audio data). The packet combining unit 17 may notify the packet combining unit 17 of whether or not the packet is a piece, and create the header information based on the content of the notification.
[0082]
Further, the data output switching unit 26 automatically determines whether or not the data piece supplied from the data separation unit 24 is an audio data piece based on a correlation with the audio data piece separated by the data separation unit 24. You may do so. More specifically, the data output switching unit 26 obtains a data fragment (a data fragment generated by the data selecting unit 16) from the data demultiplexing unit 24, and extracts a voice data fragment belonging to the same DV packet as the data fragment. Obtained from the separation unit 24, a correlation coefficient between the data piece and the audio data piece is obtained. It may be determined that there is (that is, time diversity is applied to the GMSK modulated wave received by the GMSK receiver 2).
[0083]
The time diversity apparatus and the time diversity method according to the present invention have been described above. However, the time diversity apparatus according to the present invention can be realized using a general computer system without using a dedicated system.
[0084]
For example, a personal computer including a microphone, an A / D converter, a serial interface, a GMSK modulator, a high-frequency amplifier, and the like may be connected to the data input unit 11, the audio input unit 12, the audio compression unit 13, the pseudo data storage unit 14, The program is installed from a medium (flexible disk, CD-ROM, or the like) storing a program for executing the operations of the control unit 15, the data selection unit 16, the packet synthesis unit 17, the modulation unit 18, and the modulation wave output unit 19. Thus, the GMSK transmitter 1 that executes the above processing can be configured.
[0085]
In addition, a personal computer including a GMSK demodulator, a smoothing circuit, a serial interface, a D / A converter, a speaker, and the like is provided with the above-described modulated wave input unit 21, level recording unit 22, demodulation unit 23, data separation unit 24, switching control The above processing is performed by installing a program for executing the operations of the unit 25, the data output switching unit 26, the data selection / synthesis unit 27, the audio decompression unit 28, and the audio reproduction unit 29 from a storage medium. The GMSK receiver 2 to be executed can be configured.
[0086]
Further, for example, the program may be uploaded to a bulletin board (BBS) of a communication network and distributed via the network. Distribution via a network may be performed by transmitting a modulated wave obtained by modulating a carrier by the program.
Then, by starting this program and executing it in the same manner as other application programs under the control of the OS, the above-described processing can be executed.
[0087]
When the OS shares a part of the processing, or when the OS constitutes a part of one component of the present invention, the program excluding the part is stored in the recording medium. You may. Also in this case, in the present invention, it is assumed that the recording medium stores a program for executing each function or step executed by the computer.
[0088]
【The invention's effect】
As described above, according to the present invention, a transmission device, a reception device, a transmission method, a reception method, and a program for efficiently transmitting and receiving data while performing a time diversity method are realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a basic configuration of a GMSK transmitter according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a data structure of a data stream when time diversity is not performed.
FIG. 3 is a diagram showing a data structure of a data stream when time diversity is performed.
FIG. 4 is a block diagram showing a basic configuration of a GMSK receiver according to the embodiment of the present invention.
FIG. 5 is a diagram for explaining a method of time diversity reception.
[Explanation of symbols]
1 GMSK transmitter
11 Data input section
12 Voice input section
13 Audio compression unit
14 Pseudo data storage unit
15 Selection control unit
16 Data selection section
17 Packet synthesis unit
18 Modulation section
19 Modulation wave output section
2 GMSK receiver
21 Modulation wave input section
22 level recording section
23 Demodulation unit
24 Data separation unit
25 Switching control unit
26 Data output switching unit
27 Data Selection / Synthesis Unit
28 Audio decompression unit
29 Audio playback unit

Claims (11)

A transmitting apparatus for transmitting a packet including a first portion for storing a first type of data and a second portion for storing a second type of data,
Transmission mode determining means for determining whether to transmit the second type of data;
When the transmission mode determining means determines that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the packet or another packet. Packet storage means for further storing in the second part of
Packet sending means for sending out a packet storing the first type of data.
A transmitting device characterized by the above-mentioned. When the transmission mode determining means determines that the second type of data is not to be transmitted, the packet storing means stores the first type of data in the first portion of the packet, and stores the first type of data. Further storing in the second part of the packet other than the packet;
The transmitting device according to claim 1, wherein: The transmission mode determining means obtains information designating whether to transmit the second type of data from outside, and determines whether to transmit the transmission target data according to the specification by the information.
The transmission device according to claim 1, wherein: The transmission mode determining means determines whether or not a second type of data is externally supplied to the packet storage means, and when determining that the data is supplied, determines that the transmission target data is to be transmitted. When it is determined that the data to be transmitted is not supplied, it is determined that the data to be transmitted is not transmitted.
The transmission device according to claim 1, wherein: When the transmission mode determining unit determines that the second type of data is not transmitted, the packet storing unit stores or adds control data indicating that time diversity has been applied to the first type of data to the packet.
The transmission device according to any one of claims 1 to 4, wherein: A receiving apparatus for receiving a packet including a first part to store a first type of data and a second part to store a second type of data,
Packet receiving means for receiving one or more packets and specifying the level of the reception level at the time of receiving each part of the packets;
Transmission mode determining means for determining whether or not the packet received by the packet receiving means includes the second type of data;
When the transmission mode determining unit determines that the packet received by the packet receiving unit does not include the second type of data, the transmission mode determining unit specifies a plurality of first type data identical to each other included in the packet, Data selection means for selecting and outputting the part having the higher reception level from among the common parts of the specified first type of data,
A receiving device characterized by the above-mentioned. The transmission mode determination means detects whether or not control data indicating that time diversity has been applied to the first type of data is stored or added to the packet received by the packet reception means, and the detection of the detection is performed. Based on the result, determine whether the packet contains the second type of data,
The receiving device according to claim 6, wherein: A transmission method for transmitting a packet including a first portion to store a first type of data and a second portion to store a second type of data,
Determining whether to transmit the second type of data,
When it is determined that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the second portion of the packet or another packet. Also stored in
Sending a packet in which the first type of data is stored;
A transmission method characterized in that: A receiving method for receiving a packet including a first portion to store a first type of data and a second portion to store a second type of data,
Receiving one or more packets, specifying the level of the reception level at the time of receiving each part of the packet,
Determine whether the received packet contains the second type of data,
When it is determined that the received packet does not include the second type of data, a plurality of first type data identical to each other included in the packet are identified, and each of the identified first type data is identified. Select and output the part with the higher reception level from the common parts of
A receiving method, characterized in that: A program for causing a computer to function as a transmitting device that sends out a packet including a first portion to store a first type of data and a second portion to store a second type of data, The computer
Transmission mode determining means for determining whether to transmit the second type of data;
When the transmission mode determining means determines that the second type of data is not transmitted, the first type of data is stored in the first portion of the packet, and the first type of data is stored in the packet or another packet. Packet storage means for further storing in the second part of
Packet sending means for sending a packet storing the first type of data;
Program to make it work. A program for causing a computer to function as a receiving device that receives a packet including a first portion to store a first type of data and a second portion to store a second type of data, The computer
Packet receiving means for receiving one or more packets and specifying the level of the reception level at the time of receiving each part of the packets;
Transmission mode determining means for determining whether or not the packet received by the packet receiving means includes the second type of data;
When the transmission mode determining unit determines that the packet received by the packet receiving unit does not include the second type of data, the transmission mode determining unit specifies a plurality of first type data identical to each other included in the packet, Data selecting means for selecting and outputting the portion having the higher reception level from among the common portions of the identified first type data,
Program to make it work.

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