JP2000261398A - Communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain communication equipment for efficiently transmitting real time information and non-real time information through giving priority to real time information by switching a transmission rate in accordance with the quality of a transmission line. SOLUTION: In the communication equipment, a receiving means formed of an antenna 11, a receiver 12, e.g. receives a signal; a switching means formed of an adaptive modulation control circuit 13 switches a transmission rate to a low one when the quality of a transmission line based on the received signal is low and switches the rate to a high one when the quality is high; and a transmission means formed of a multiplex circuit 2, a transmitter 3 and an antenna 4 transmits only real time information when the transmission rate is switched to the low one and multiplexes and transmits real time information and non-real time information when the transmission rate is switched to the high one.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device for transmitting real-time information and non-real-time information, and more particularly, to a method for transmitting real-time information by switching a transmission rate in accordance with the quality of a line (transmission line) used for information transmission. The present invention relates to a communication device that efficiently transmits non-real-time information with priority.

[0002]

2. Description of the Related Art In a communication device that multiplexes real-time information such as voice and non-real-time information such as data for communication (eg, multimedia communication), non-real-time information such as voice is used as an instantaneous stop time. Transmission of data or the like, which is real-time information, is performed. Here, the real-time information is information that is required to be transmitted in real time, and includes, for example, voice in a telephone or a video conference (for example, voice of a conversation) and an image in a video conference (for example, a video of a conference). is there. The non-real-time information is information that is not required to be transmitted in real time, and includes, for example, text data, audio data, image data, and the like.

FIG. 3 shows an example of a communication system for performing the above-described multiplex communication. In this communication system, voice is transmitted as real-time information, and data such as images is transmitted as non-real-time information. . In the transmitting apparatus of the communication system shown in FIG. 1, first, audio to be transmitted is input to an encoding circuit 21 and an audio presence / absence detecting circuit 22, and the encoding circuit 21 encodes the audio by a predetermined encoding algorithm. The voice presence / absence detection circuit 22 detects a silent section (a momentary interruption portion) of the voice and outputs information on the silent section to the multiplexing circuit 23.

[0004] Next, in the transmitting device, the multiplexing circuit 23 divides the data to be transmitted and inserts the divided data into a portion corresponding to a silent section in the audio data string input from the encoding circuit 23, so that the audio and data are transmitted. Are multiplexed, and the multiplexed data sequence obtained by the multiplexing is output to the transmitter 24. Note that a portion corresponding to a silent section in the audio data string is detected based on the information from the audio presence / absence detection circuit 22 described above.

FIG. 4 conceptually shows a method of inserting data into a silent section in a coded audio data sequence. As shown in the figure, in general, voices such as conversations are not always continuously emitted, and there are times when no voices are generated (silent sections). The multiplexing circuit 23 multiplexes data using such a silent section of the voice. Specifically, the multiplexing circuit 23 converts the data to be transmitted into a plurality of data portions ("DATA1") corresponding to the length of each silent section. "," DATA2 ", ...," DAT
An ") and multiplexing is performed by inserting each data portion into each silent section.

Next, in the transmitting device, the transmitter 24 modulates the multiplexed data sequence input from the multiplexing circuit 23, converts the frequency, performs power amplification and the like, and transmits the multiplexed data sequence from the antenna (antenna) 25. Transmit as a radio signal. On the other hand, in the receiving apparatus of the communication system shown in FIG. 3, when a signal wirelessly transmitted from the transmitting apparatus is received by the antenna 31, first, the receiver 32 power-amplifies the signal, performs frequency conversion, and demodulates the signal. In this way, the multiplexed data string reproduced thereby is output to the separation circuit 33.

Next, in the receiving apparatus, the separating circuit 33 extracts and outputs only data which is non-real-time information from the multiplexed data string input from the receiver 32, and outputs the data.
The audio data string thus separated is output to the decoding circuit 34. As a method of extracting only data from the multiplexed data sequence, for example, when the transmitting device inserts data into a silent section of a voice, a header including information such as a data length is added to the transmitting device, and the receiving device transmits the data. A method such as referring to the header can be used. Next, in the receiving device, the decoding circuit 34 decodes the audio data string input from the separation circuit 33 into the original audio by a decoding method corresponding to the transmitting device.

However, in the above-described conventional transmission apparatus, it takes time to detect the presence / absence of real-time information (in this example, the above-described silent section). There was a problem that processing was delayed. Further, for example, some real-time information does not have an instantaneous interruption part such as music or a moving image, and multiplex communication using the instantaneous interruption part cannot be performed on such real-time information. There was such a problem.

Next, the adaptive modulation method will be described. For example, "Transmission characteristic analysis of symbol rate / modulation multi-level variable adaptive modulation system Hidehiro Matsuoka, Toyoki Kami, Seiichi Sampei, Norihiko Morinaga IEICE Technical Report RCS94-64 (199
4-09) ”describes a technique of an adaptive modulation scheme in which a transmitting apparatus detects the quality of a transmission line and switches a modulation scheme used for information transmission according to the quality. The adaptive modulation scheme is a technique that can improve communication quality indicated by an average transmission rate (here, an average value of the transmission rate), a bit error rate, and the like by switching the modulation scheme according to the quality of a transmission line. is there.

FIG. 5 conceptually shows an example of information communication controlled using the above-mentioned adaptive modulation scheme. The horizontal axis represents time, and the vertical axis represents RSSI (Receiviv) at each time.
ed Signal Strength Indicator) and the modulation scheme to be switched. In the figure, as an example, QP
SK (2bit / symbol) and 16QAM (4bi
t / symbol) and 64QAM (6 bits / symb)
ol) are switched according to the quality of the transmission line. In addition, RSSI is used as the transmission line quality information as described above. If the RSSI is large, the transmission line quality is high,
If the RSSI is small, it indicates that the quality of the transmission line is low.

As shown in FIG. 5, when the quality of the transmission line is low (that is, when the quality is relatively deteriorated), the information is transmitted by switching to the modulation method of the low transmission rate and the transmission line is transmitted. When the quality is high (that is, when the quality is relatively good), the information is transmitted by switching to the modulation method of the high transmission rate. Specifically, in a state where the RSSI is large (for example, between “R2” and “R3”), switching to 64QAM having the largest transmission rate is performed to increase the information transmission amount, and a state where the RSSI is small (for example, “R0” and “R0”). R1 "
), The information transmission amount is reduced by switching to QPSK having the smallest transmission rate, and in a state where the RSSI is intermediate between them (for example, between “R1” and “R2”), an intermediate transmission rate is used. Switch to 16QAM and transmit information.

The reason for performing the switching control as described above is that, in general, the modulation method is more susceptible to the deterioration of the channel quality as the information amount per symbol is larger, and the modulation method is more resistant to the deterioration of the line quality as the information amount per symbol is smaller. It is. That is, if information is transmitted at a high transmission rate when the quality of the line is low, many transmission errors occur, and normal information transmission cannot be performed.

When the switching control of the modulation scheme as shown in FIG. 5 is performed, both the average transmission rate and the communication quality can be improved in a state where the RSSI is large.
When I is small, the communication quality can be improved by lowering the average transmission rate. Note that FIG.
An example of the relationship between SI and the average transmission rate is schematically shown, in which the horizontal axis represents RSSI and the vertical axis represents the average transmission rate.

As described above, the use of the adaptive modulation scheme can improve the quality of information transmission and the like. However, when the above-described adaptive modulation scheme is adopted, the transmission rate changes with time according to the quality of the transmission line. Therefore, it is designed to perform information communication at a constant speed (constant transmission rate), for example. However, there is a problem that the adaptive modulation scheme cannot be applied as it is to a communication system. For this reason, it has been required to figure out how to make good use of the adaptive modulation scheme.

As a solution to such a problem,
"Transmission characteristics of variable modulation level adaptive modulation scheme under transmission delay time limitation" Kamio et al. IEICE Technical Report R
CS94-67 (1994-09) "discusses a method of fixing the transmission rate using a data buffer, but this method has the following problems although the transmission rate is fixed. . In other words, in this method, if the state of the transmission line has a high quality for a long time, waste due to transmission of dummy data or the like occurs, and if the state of the transmission line has a low quality for a long time, a state of a high quality occurs. However, even if the modulation scheme of the intermediate level is forcibly applied (for example, FIG.
In the case of (1), it is fixed to 16 QAM), so that the advantage of the adaptive modulation method cannot be fully utilized.

[0016]

As described above, in a conventional transmitting device for transmitting, for example, real-time information and non-real-time information, it takes time to detect the presence or absence of real-time information. There was a problem that it was delayed. Further, the conventional multiplex communication method using the instantaneous interruption part has a problem that multiplex communication with non-real-time information cannot be performed for real-time information having no instantaneous interruption part. Further, as described above, for example, in a conventional adaptive modulation scheme in which a transmission rate is switched in accordance with the quality of a transmission line, it has been required to come up with how to effectively use such a scheme.

The present invention has been made to solve such a conventional problem, and effectively utilizes a technique for switching a transmission rate in accordance with the quality of a transmission line to convert real-time information and non-real-time information. It is an object of the present invention to provide a communication device capable of efficiently transmitting real-time information with priority. More specifically, the communication device of the present invention makes it possible to omit the process of detecting the presence / absence of real-time information, and to multiplex non-real-time information even with real-time information having no instantaneous interruption part. Enable communication.

[0018]

In order to achieve the above object, a communication device according to the present invention transmits real-time information and non-real-time information as follows. That is, the receiving unit receives the signal, and the switching unit switches to a low transmission rate when the quality of the transmission line based on the received signal is low, while switching to a high transmission rate when the quality is high, and When the transmission rate is switched, only the real-time information is transmitted. When the transmission rate is switched to a high transmission rate, the real-time information and the non-real-time information are multiplexed and transmitted.

Therefore, by effectively utilizing the technique of switching the transmission rate according to the quality of the transmission line, real-time information and non-real-time information can be transmitted efficiently by giving priority to real-time information. The present invention focuses on the characteristic that real-time information needs to be transmitted in real time, while non-real-time information does not always need to be transmitted in real time, and skillfully employs such a characteristic and a technology for switching a transmission rate. It is tied.

As described above, according to the present invention, the transmission rate is increased by utilizing the time when the quality of the transmission line is high, and the non-real-time information is multiplexed with the real-time information and transmitted. In the case of voice, a process of detecting a silent section can be omitted. For example, even for real-time information in which there is no instantaneously interrupted portion (for example, a silent section in the case of voice), it is multiplexed with non-real-time information. Can be sent.

In the communication device according to the present invention, real-time information and non-real-time information are multiplexed and transmitted as follows. That is, the receiving means receives the signal, and the switching means switches to a low transmission rate if the quality of the transmission line based on the received signal is low, while switching to a high transmission rate if the quality is high, and the transmission means switches. The multiplexing ratio between the real-time information and the non-real-time information is changed by giving priority to the real-time information in accordance with the transmission rate, and information multiplexed at the multiplexing ratio is transmitted.

Therefore, as in the case of the above-described communication device, the technique of switching the transmission rate according to the quality of the transmission line is effectively utilized, and real-time information and non-real-time information are efficiently given priority over real-time information. Can be sent. In the communication device described above, only real-time information is transmitted when the transmission rate is low. However, in the present communication device, not only real-time information but also non-real-time information is transmitted even when the transmission rate is low. This is a configuration in which a transmission rate that can also transmit data is secured.

In the communication apparatus according to the present invention described above, as a preferred embodiment, the above-mentioned switching means switches from a plurality of transmission rates to the maximum transmission rate allowed according to the quality. Therefore, for example, a plurality of transmission rates are set in advance in the communication device, and by switching from the plurality of transmission rates to the maximum transmission rate allowed according to the quality of the transmission line, information transmission efficiency is improved. Can be further achieved.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment according to the present invention will be described with reference to the drawings. In this example, a case is shown in which the present invention is applied to a communication device of a digital wireless communication system. As an example, the communication device is QPSK (2 bit / symbo).
l) and 16QAM (4bit / symbol) and 64Q
A case is shown in which real-time information and non-real-time information are wirelessly communicated by switching three types of modulation schemes such as AM (6 bits / symbol) according to the quality of a communication line.

FIG. 1 shows an example of a communication device according to the present invention. The communication device has an encoding circuit 1 for encoding real-time information, and multiplexes real-time information and non-real-time information. A multiplexing circuit 2, a transmitter 3 for wirelessly transmitting a multiplexed data sequence from an antenna 4, a receiver 12 for receiving a wireless signal by an antenna 11, and information transmission according to the quality of a transmission line based on the received signal. Adaptive modulation control circuit 13 for switching the modulation method, and symbol determination circuit 1 for determining a received symbol (symbol)
4, a separation circuit 15 for separating the multiplexed data sequence into real-time information and non-real-time information, and a decoding circuit 16 for decoding the separated real-time information.

The encoding circuit 1 inputs real-time information such as audio and images to be transmitted, encodes the real-time information into digital data by a predetermined encoding method, and converts the digital data (encoded real-time information). It has a function of outputting to the multiplexing circuit 2.

The multiplexing circuit 2 outputs only the encoded real-time information input from the encoding circuit 1 to the transmitter 3 in accordance with the modulation scheme information from the adaptive modulation control circuit 13 described later, or outputs the image to be transmitted. Inputting non-real-time information such as data (in FIG. 1, the non-real-time information is referred to as “data”), multiplexing the non-real-time information (digital data) and the encoded real-time information, and outputting the multiplexed information to the transmitter 3 Has the function of performing A specific example of the multiplexing method will be described later.

The transmitter 3 inputs coded real-time information alone or multiplexed data of coded real-time information and non-real-time information from the multiplexing circuit 2, and inputs the input information (ie, coded real-time information or multiplexed data). Is mapped to a symbol of a modulation scheme specified by modulation scheme information from the adaptive modulation control circuit 13 described later, and has a function of performing orthogonal modulation, frequency conversion, power amplification, and the like, and wirelessly transmitting the information from the antenna 4. ing.

The receiver 12 receives a signal wirelessly transmitted from a communication partner (not shown) by the antenna 11, amplifies the received signal, converts the frequency, performs quadrature detection, etc., and then obtains a complex baseband signal obtained by this. Is output to the symbol determination circuit 14. Further, the receiver 12 of the present example has a function of outputting information relating to the quality of the transmission line (transmission line quality information) to the adaptive modulation control circuit 13 based on the received signal. In this example, the receiver 12 receives a signal using the antenna 11 to constitute a receiving unit that receives the signal.

Here, the transmission line quality information output from the receiver 12 to the adaptive modulation control circuit 13 of the present embodiment will be described in detail. In this example, as an example, for example, TDD (Ti
It is assumed that the communication device communicates with the communication partner using a system in which the transmission line and the reception line are the same (for example, the carrier frequency is the same), such as the me Division Duplex system. RSSI of the signal
And outputs the RSSI to the adaptive modulation control circuit 13 as transmission line quality information. In the case of transmitting and receiving a signal using the same line as the communication partner as in this example, the state of the line used for receiving information from the communication partner and the state of the line used for transmitting information to the communication partner are the same. Therefore, the adaptive modulation control circuit 13 described later can estimate the quality of the transmission line at the next transmission timing based on the RSSI of the received signal notified from the receiver 12.

As another example, for example, FDD (Freq
When a transmission line and a reception line are different (for example, the carrier frequency is different) as in the case of the uency division duplex), the state of the line used for receiving information from the communication partner and the communication partner are different. Is different from the status of the line used for transmitting information to the communication device. For example, the communication partner of the communication device is provided with line quality information based on a signal received from the communication device (eg, RSSI of the received signal).
Is added to a signal to the communication device to notify the communication device. In such a case, the receiver 12 of the communication apparatus outputs the line quality information received from the communication partner to the adaptive modulation control circuit 13 as transmission line quality information in the form of, for example, a complex baseband signal. The control circuit 13 can estimate the quality of the transmission line at the next transmission timing based on the information.

The adaptive modulation control circuit 13 switches the modulation scheme used for information transmission according to the quality of the transmission link based on the transmission link quality information input from the receiver 12, and specifies the switched modulation scheme (modulation scheme information). Is output to the multiplexing circuit 2 and the transmitter 3. Specifically, in this example, as described above, QPSK, 16QAM, and 64QAM
Are switched in accordance with the quality of the transmission line, and this switching will be described in detail.

In the adaptive modulation control circuit 13 of the present embodiment, for example, the quality of the transmission line (for example, RSSI value, etc.) and the modulation system to be switched are set in association with each other. Is relatively high (ie, good), switch to 64QAM with the highest transmission rate, and the quality of the transmission line is relatively low (ie, poor).
In such a case, switching is performed to QPSK with the lowest transmission rate, and if the quality of the transmission line is intermediate between these, switching is performed to 16QAM with an intermediate transmission rate.

The adaptive modulation control circuit 13 of this embodiment estimates the quality of the transmission line at the next transmission timing based on the above setting and the transmission line quality information input from the receiver 12,
Switching to the modulation method corresponding to the estimated quality, and transmitting the modulation method information designating the modulation method to the multiplexing circuit 2 or the transmitter 3
Output to The switching of the modulation scheme may be performed at any timing, but in the present example, the modulation scheme is switched for each frame used for communication as a preferable mode.

As a method of estimating the quality of the transmission line at the next transmission timing, for example, when the quality of the transmission line changes gradually, the quality of the current transmission line and the quality at the next transmission timing are compared. Can be estimated assuming that the quality is the same, and when the quality of the transmission line changes relatively quickly, for example, by considering the pattern of the quality change, the next transmission timing Quality can be estimated.

In the present embodiment, the adaptive modulation control circuit 13 switches the modulation method based on the transmission line quality information from the receiver 12 to switch the transmission rate as described above, and thereby the quality of the transmission line based on the received signal. The switching means is configured to switch to a low transmission rate when is low, and to switch to a high transmission rate when the quality is high.

When the transmission line and the reception line are the same as in the present embodiment, for example, the S / N ratio (signal-to-noise ratio) of the received signal is detected in addition to the above RSSI. It is also possible to detect the quality of the receiving line. Further, as the quality of the transmission line, it is not always necessary to specify a strict quality (for example, a strict RSSI value or the like).
For example, the quality may be specified to a degree that is practically effective. Further, the present invention is not limited to the mode shown in the present example, and various methods for switching the transmission rate based on the quality of the transmission line may be used.

In the present embodiment, as a preferred mode, the above-described adaptive modulation control circuit 13 switches from the three types of modulation systems to the modulation system having the maximum allowable transmission rate according to the quality of the transmission line. Has a function. That is, in this example, the above-mentioned switching means switches the transmission rate from the plurality of transmission rates to the maximum allowable transmission rate according to the quality of the transmission line.

The multiplexing processing in the multiplexing circuit 2 performed in accordance with the modulation scheme information output from the adaptive modulation control circuit 13 will be described in detail. As described above, the multiplexing circuit 2 performs the multiplexing process according to the modulation scheme information from the adaptive modulation control circuit 13. Specifically, the multiplexing circuit 2 of the present example
When QPSK is specified by the modulation method information, only the coded real-time information input from the coding circuit 1 is output to the transmitter 3 without performing multiplexing processing, while 16QAM or 64QAM is specified by the modulation method information. In this case, the coded real-time information and the non-real-time information input from the coding circuit 1 are multiplexed and output to the transmitter 3.

Here, in the present embodiment, as a preferable mode,
Modulation scheme with the lowest transmission rate (QPSK in this example)
In the case where information is transmitted by using real time information, real time information can be transmitted in real time. In this example, the transmission rate of QPSK and the transmission rate required to transmit real time information in real time are given as examples. Shows a case in which is matched. That is,
In this example, it is assumed that the transmission rate required for transmitting real-time information to be transmitted in real time is always constant (or almost constant), and real-time information is transmitted in real time regardless of the modulation method. To be transmitted with priority.

Further, as a specific example of the multiplexing ratio, for example, when QPSK is used, the information transmission amount per frame is N bits per unit time (in this example, the information amount is the same as the encoded real-time information amount). Then, 16QA
Since the information transmission amount per frame when M is used is 2N bits per unit time, the multiplexing circuit 2 of this example is used.
Performs multiplexing processing when the multiplexing ratio between the encoded real-time information and the non-real-time information is 1: 1 when 16QAM is designated. Similarly, the amount of information transmitted per frame when using 64QAM is 3N bits per unit time.
When 4QAM is specified, the multiplexing process is performed with the multiplexing ratio between the encoded real-time information and the non-real-time information being 1: 2.

As described above, in a preferred embodiment, the multiplexing circuit 2 of the present embodiment sets the transmission rate to a high value at which not only real-time information but also non-real-time information can be transmitted. The non-real-time information is multiplexed using it without excess. That is, the multiplexing circuit 2 of the present embodiment multiplexes as much non-real-time information as possible into the real-time information while giving priority to the real-time information according to the specified transmission rate.

In this example, the multiplexing circuit 2
Or the transmitter 3 transmits only real-time information when a low transmission rate QPSK is specified, and multiplexes and transmits real-time information and non-real-time information when a high transmission rate 16QAM or 64QAM is specified. By doing so, transmission means is configured to transmit only real-time information when switched to a low transmission rate, and multiplex and transmit real-time information and non-real-time information when switched to a high transmission rate. I have.

In this example, the real-time information to be transmitted is continuous information and has no instantaneous interruption part. However, for example, real-time information having an instantaneous interruption part can be used as the transmission target. . In addition, in this example, as described above, the configuration is such that real-time information can be transmitted in real time even when information is transmitted by switching to the lowest transmission rate, for example, when the quality of the transmission line is very poor If it is permissible to reduce the amount of information by thinning out the real-time information, for example, a configuration that can be switched to a transmission rate that is low enough to transmit the thinned-out real-time information may be used. Good.

As described above, in this example, when a relatively low transmission rate (in this example, QPSK having the lowest transmission rate) is used, only real-time information is transmitted. Even if it is used, if there is a margin that the real-time information and the non-real-time information can be multiplexed and transmitted,
It is also possible to adopt a configuration in which the real-time information and the non-real-time information are always transmitted, and the multiplexing ratio of the real-time information and the non-real-time information is changed by giving priority to the real-time information according to the transmission rate.

In such a configuration, for example, assuming that the amount of real-time information per unit time is constant (or substantially constant), the multiplexing ratio of non-real-time information may be increased as the transmission rate is switched to a higher transmission rate. It is possible. When the configuration for always multiplexing the real-time information and the non-real-time information is used, the communication device gives priority to the real-time information and the non-real-time information in accordance with the transmission rate switched by the switching unit. Transmission means for changing the multiplexing ratio with the multiplexing ratio and transmitting information multiplexed at the multiplexing ratio.

The symbol determination circuit 14 detects the modulation scheme used for modulating the received signal based on the complex baseband signal input from the receiver 12, and determines the received symbol based on the detection result. Each of the determined symbol data is converted into a bit stream and separated by a separation circuit 15.
It has the function of outputting to In this example, the communication partner of the communication device of the present embodiment also performs communication by switching a plurality of modulation schemes, and the communication device and the communication partner of the present embodiment use the modulation of the signal in the signal to be transmitted. It is assumed that information on the modulation method is included.

The above-mentioned symbol is a unit of information in information communication, and is, for example, 1 in QPSK.
A symbol can contain 2 bits of information, and 16Q
In AM, one symbol can include four bits of information, and in 64QAM, one symbol can include six bits of information. The larger the number of bits that can be included in one symbol, the higher the transmission rate.

The separating circuit 15 determines whether non-real-time information is multiplexed in the bit stream based on the bit stream input from the symbol determining circuit 14, and determines that the non-real-time information is not multiplexed. If it is determined, the input bit stream (that is, the encoded real-time information) is output to the decoding circuit 16, while if it is determined that non-real-time information is multiplexed, the input bit stream is encoded. The decoding circuit 16 separates the encoded real-time information from the non-real-time information, and
And a function of outputting the separated non-real-time information to, for example, a memory (not shown).

Here, whether or not non-real-time information is multiplexed in a bit stream can be determined based on, for example, the length of the bit stream. Specifically, for example, assuming that the information transmission amount per frame when using QPSK as described above is N bits per unit time, in this example, the bit stream length per frame is longer than N bits Can determine that non-real-time information is multiplexed, and the bit stream length per frame is N
If it is a bit, it can be determined that the non-real-time information is not multiplexed. Note that any method may be used to determine whether non-real-time information is multiplexed, for example, based on the modulation method used for communication.

The decoding circuit 16 decodes the coded real-time information input from the separation circuit 15 in accordance with the coding method of the communication partner, thereby reproducing and outputting the original real-time information such as voice and image. Has a function. With the configuration described above, in the communication device of the present example, the adaptive modulation control circuit 13 switches the modulation method used for information transmission according to the quality of the transmission line based on the signal received by the receiver 12,
As a result, when switching to QPSK is performed, the transmitter 3 wirelessly transmits only the real-time information encoded by the encoding circuit 1, while when switching to 16QAM or 64QAM, the multiplexing circuit 2 transmits the encoded real-time information. And the non-real-time information, and the transmitter 3 wirelessly transmits the multiplexed data.

In the communication apparatus of the present embodiment, for example, the symbol determination circuit 1 based on a signal received by the receiver 12 is used.
4 determines the symbol and converts each symbol data into a bit stream. If non-real-time information is multiplexed in the bit stream, the separating circuit 15 separates the non-real-time information and decodes the non-real-time information. Circuit 16
Decodes the received encoded real-time information.

Here, FIG. 2 shows an example of a modulation system switching process and a method of multiplexing real-time information and non-real-time information performed by the communication apparatus of the present embodiment, and a graph shown in FIG. The horizontal axis indicates the time, and the vertical axis indicates the quality of the transmission line and the modulation scheme to be switched.
It should be noted that the non-real-time information is shown as “data” in FIG.

As shown in the figure, in the communication apparatus of the present embodiment, when the quality of the transmission line is low (poor) (for example, when the quality is lower than the preset reference "P1"), the modulation method is QPSK. To transmit only real-time information, and when the quality of the transmission line is high (good) (for example, higher than a preset reference "P2"), the modulation method is switched to 64QAM to switch the real-time information and non-real-time information. Multiplexed and transmitted, and when the quality of the transmission line is intermediate between these (for example, the above-described reference “P1”
And the reference "P2"), the modulation method is 16QA
Switch to M and multiplex and transmit real-time information and non-real-time information.

As described above, in the communication apparatus according to the present embodiment, real-time information and non-real-time information can be transmitted efficiently with priority given to real-time information by switching the transmission rate according to the quality of the transmission line. . Also,
In the communication device of this example, real-time information and non-real-time information can be multiplexed and transmitted without performing a process of detecting the presence or absence of real-time information (for example, a silent section in the case of voice). Even in the case of real-time information having no (for example, a silent section in the case of voice), it can be multiplexed with non-real-time information and transmitted.

Here, in the communication apparatus shown in the above embodiment, three types of transmission rates are switched by switching three types of modulation schemes. However, the number of switchable transmission rates is not particularly limited as long as the number is plural. Instead, for example, a configuration in which two types of transmission rates are switched, or a configuration in which four or more types of transmission rates are switched, for example, may be used.

Further, in the above embodiment, the transmission rate is switched by switching a plurality of modulation schemes having different modulation levels, but for example, even when the same modulation scheme is used, the transmission rate is switched by switching the symbol rate. Can be switched. For this reason, for example, a configuration in which the transmission rate is switched by switching the symbol rate may be used,
Further, for example, a configuration in which switching of the modulation scheme and switching of the symbol rate are used in combination may be used.

The real-time information and non-real-time information transmitted by the communication device according to the present invention include:
Various types may be used, for example, information such as voice, image, text, etc. can be transmitted. In addition, as media for real-time information and non-real-time information,
They may be the same or different.

The configuration of the communication device according to the present invention is not necessarily limited to the above-described configuration, and various configurations may be used. As an example, the receiving unit, the switching unit, and the transmitting unit of the communication device according to the present invention may be configured such that a processor executes a control program in a hardware resource including a processor and a memory, for example. Each of these functional units may be configured as an independent hardware circuit, for example.

The field to which the communication apparatus according to the present invention is applied is not particularly limited, and the present invention can be applied to communication terminals and base stations of various communication systems. As an example, when the present invention is applied to, for example, a communication terminal or a base station of a PHS (Simplified Mobile Phone) system employing the TDD scheme, the transmission line and the reception line used by the communication device are the same. This is preferable in that the quality of the transmission line can be determined based on the RSSI or the like of the received signal. The present invention can be applied to, for example, a device that performs wired communication.

[0061]

As described above, according to the communication apparatus of the present invention, when transmitting real-time information and non-real-time information, if the quality of the transmission line based on the received signal is low, the transmission rate is switched to a low transmission rate. Technology that transmits only real-time information and multiplexes real-time information and non-real-time information when the quality is high, and switches the transmission rate according to the quality of the transmission line , The real-time information and the non-real-time information can be transmitted efficiently by giving priority to the real-time information.

Further, in the communication apparatus according to the present invention, when multiplexing real-time information and non-real-time information and transmitting the multiplexed signal, if the quality of the transmission line based on the received signal is low, the transmission rate is switched to a low transmission rate. Is higher, the transmission rate is switched to a higher transmission rate, and the multiplexing ratio between the real-time information and the non-real-time information is changed by giving priority to the real-time information according to the switched transmission rate. Non-real-time information can be transmitted efficiently by giving priority to real-time information. Further, in the communication apparatus according to the present invention, when the transmission rate is switched as described above, the transmission rate is switched from the plurality of transmission rates to the maximum transmission rate allowed according to the quality of the transmission line. Efficiency can be further improved.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an example of a communication device according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating an example of a modulation scheme switching process performed by a communication device and a method of multiplexing real-time information and non-real-time information.

FIG. 3 is a diagram illustrating an example of a communication system according to a conventional example.

FIG. 4 is a diagram for explaining a conventional method of multiplexing real-time information and non-real-time information.

FIG. 5 is a diagram illustrating an example of information communication controlled using an adaptive modulation scheme.

FIG. 6 is a diagram illustrating an example of a relationship between RSSI and an average transmission rate.

[Explanation of symbols]

1 ··· coding circuit, 2 ··· multiplexing circuit, 3 ··· transmitter, 4, 11 · · antenna, 12 ··· receiver, 13
..Adaptive modulation control circuit, 14 symbol determination circuit
15 ··· Separation circuit, 16 ··· Decoding circuit,

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (reference) H04L 27/34 H04L 13/00 307C 27/18 27/00 EF term (reference) 5K004 AA05 AA08 FA05 FE00 FF02 JA03 JE00 JF01 5K014 FA11 5K028 AA11 KK01 KK03 LL12 5K034 AA01 CC02 CC05 HH01 HH02 HH12 HH16 MM08 MM11 MM24 MM31 5K067 AA13 AA23 DD51 DD52 DD53

Claims (3)

[Claims] 1. A communication device for transmitting real-time information and non-real-time information, comprising: a receiving means for receiving a signal; and a low transmission rate when the quality of a transmission line based on the received signal is low, while the quality is low. A switching means for switching to a high transmission rate when the transmission rate is high, and transmitting only real-time information when the transmission rate is switched to a low transmission rate, and multiplexing the real-time information and non-real-time information when the transmission rate is switched to a high transmission rate. A communication device, comprising: a transmitting unit that transmits the data. 2. A communication device for multiplexing and transmitting real-time information and non-real-time information, comprising: receiving means for receiving a signal; and switching to a low transmission rate when the quality of a transmission line based on the received signal is low. A switching unit that switches to a high transmission rate when the quality is high; and a multiplexing ratio between the real-time information and the non-real-time information that is prioritized in accordance with the switched transmission rate. A communication device, comprising: transmission means for transmitting multiplexed information. 3. The communication apparatus according to claim 1, wherein the switching unit switches from a plurality of transmission rates to a maximum transmission rate allowed according to the quality. .