JP2000183849A - Spread spectrum modulation variable multiplex transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable the same user to efficiently transmit pieces of information data having different transmission conditions through transmission lines of the same bandwidth by multiplexing them with respect to channels for multimedia communication. SOLUTION: This device is equipped with a circuit which calculates a signal- to-interference-noise power ratio as to one or more channels of a reception part and a circuit which decides a return transmission channel multi-valued multiplex number with the calculated value, and adds return transmission channel multi-valued multiplex number specification information 116 as the decision result to transmit data and sends them to an opposite station. A transmission part sets the channel multiplex number of transmit information data and the modulation multi-valued numbers of data modulation and spread modulation of respective channels, packet by packet, according to the transmission channel multi-valued multiplex number specification information 124 received from the opposite station and performs multiplex transmission as the same user channel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for multiplexing information data belonging to various services or various media having different transmission conditions on a transmission path of the same band and using a plurality of channels by the same user. The present invention relates to a spread spectrum multiplex transmission apparatus that can efficiently transmit data.

[0002]

2. Description of the Related Art As a modulation method for adding a digital information signal to an electric signal, there are a modulation method for changing each of the amplitude, phase and frequency of a carrier wave, and a modulation method for changing these in combination. When converting a digital information signal into a modulation signal in the case of modulating with these modulation methods, two types of modulation signals are required when one binary bit corresponds to a modulation signal of one symbol. The number of values becomes 2, and in the case of 2 bits, four types of modulation signals are required, and the modulation multi-value number becomes 4. That is, in order to make N bits of information correspond to one modulation signal, 2 ^N kinds of modulation signals are required, and the modulation multi-level number is 2 ^N. In spread spectrum transmission, the greater the number of modulation levels in data modulation, the more information data can be transmitted in the same frequency band, and the greater the number of modulation levels in spread modulation, the greater the number of channels that can be transmitted. Can be used effectively. However, the greater the number of modulation levels in both data modulation and spreading modulation, the more likely it is to be affected by propagation path fluctuations and inter-channel interference, and the transmission data error rate deteriorates, reducing the reliability of transmission. become. Therefore, the information data is distributed to a plurality of channels, and the signal of each channel is spread-modulated and multiplexed by a different spread code string, thereby lowering the modulation speed of the data modulation, thereby reducing the error rate of the transmission data. A channel multiplexing transmission system capable of transmitting a large amount of information data without deteriorating the data transmission is used.

Referring to FIGS. 8 and 9, a transmission / reception operation of a conventional spread spectrum multiplex transmission apparatus for multiplexing transmission information data by a plurality of channels will be described. FIG. 8 is a block diagram showing a configuration of a transmission section of a conventional spread spectrum multiplex transmission apparatus, and FIG. 9 is a block diagram showing a configuration of a reception section of the conventional spread spectrum multiplex transmission apparatus. As shown in FIG. 8, this example shows a case where transmission information data 512 is multiplexed and transmitted according to transmission conditions or transmission capacity, and transmission modulation section 510 includes a plurality of transmission channels (1). To (N) 511. Each of the transmission channels (1) to (N) 511 is provided with a data multi-level modulator 514 and a spread spectrum multi-level modulator 515.

In FIG. 8, transmission information data 512 is input to a data distributor 513, and the transmission information data 512 is transmitted to the data distributor 513 in accordance with transmission conditions required for transmission information data or required transmission capacity. Are distributed to parallel data corresponding to a plurality of channels of the transmission modulation section 510 and input to the corresponding transmission channels (1) to (N) 511. For example, when the transmission information data 512 is data that requires high-speed transmission, the data distributor 513 distributes the transmission information data 512 to a plurality of pieces, and The signals are supplied to the channels (1) to (N) 511 in parallel. On the other hand, when the transmission information data 512 is data requiring only a low transmission rate, the data distributor 513 transmits the transmission information data 5.
12 is supplied to one channel of the transmission modulation section 510 without distribution, for example, the transmission channel (1).

[0005] Transmission modulation section 510 includes transmission information data 5.
Twelve distributed parallel data are transmitted channels (1) to (N).
The data is input to a data multi-level modulator 511 and multi-level modulation of the data is performed, and a data multi-level modulation output is supplied to a spread spectrum multi-level modulator 515. Here, as the data multi-level modulation, for example, BPSK (Binary Phase Shift
Keying), QPSK (Quadrature Phase Shift Keyin)
g) or other phase modulation method, frequency modulation method, or 16
There is an amplitude and phase modulation method such as QAM (16 Quadrature Amplitude Modulation). In this specification, binary modulation such as BPSK is also treated as one of the multi-level modulations.

[0006] In the spread spectrum multi-level modulator 515, the output of the data multi-level modulator 514 in each transmission channel 511 is multiplied by the multi-level signal of the spread code generated from the spread encoder 516, and each transmission channel is multiplied. From (1) to (N) 511, a transmission channel multi-level signal 517 is output. Here, the above-mentioned spreading code is a code obtained by multiplying a PN code by a Walsh code or a code such as an orthogonal Gold code, and a different code sequence is used for each transmission channel.
The spread spectrum multi-level modulation includes the above-described data.
Similarly to the multi-level modulation, there are, for example, a phase modulation method such as BPSK and QPSK, a frequency modulation method, and an amplitude phase modulation method such as 16QAM. The transmission channel multi-level signal 517 output in this way is added in a multiplexing circuit 518, and a transmission multiplex signal 519 is transmitted as a channel signal of the same user.

FIG. 9 is a block diagram showing a configuration of a receiving section of a conventional spread spectrum multiplex transmission apparatus. In this example, a plurality of reception channels (1) to (N) 611 are provided in reception demodulation section 610 corresponding to a plurality of multiplexed channels, and each reception channel 611 has a spectrum despread multi-level. A demodulator 616 and a data multi-level demodulator 615 are provided. In reception demodulation section 610, reception multiplexed signal 61
8 is input to the spectrum despread multi-level demodulator 616 of each of the reception channels (1) to (N) 611 and the spread coder 61
7 is multiplied by a multi-level signal of a different spreading code sequence for each channel and returned to a data-modulated signal. Next, these signals are supplied to a data multi-level demodulator 615 of each of the reception channels (1) to (N) 611 to perform data demodulation, and a plurality of reception channel data 614 receive and demodulate. Part 61
Output from 0. A plurality of output reception channel data
The data 614 is input to the data collector 613, the parallel data distributed to the plurality of channels is converted into serial data, and the received information data 612 is output.

[0008] In this manner, transmission information data can be distributed to a plurality of channels, multiplexed, and transmitted as one user channel. However, in the above-described conventional transmission apparatus, the modulation multi-level numbers for data modulation and spread spectrum modulation and the corresponding data demodulation and spectrum despread demodulation are determined to be fixed multi-level numbers. In addition, all channels to be distributed and multiplexed are determined to have the same fixed modulation multilevel number. This generally means that the transmission device
It is considered that the maximum goal is to satisfy a certain data quality under the influence of phasing, and the above-mentioned fixed multi-level modulation value is larger than a value achievable without phasing. This is because it is set to a small value.

[0009]

In recent years, multimedia communication, which has been actively studied, requires various services and media data requiring high transmission quality and large transmission capacity. There is a demand for a technology capable of efficiently transmitting a transmission signal to be transmitted over a transmission path of the same band. However, in the conventional spread spectrum multiplex transmission apparatus, as described above, the modulation multi-level number is set to a value smaller than a value that can be realized when there is no effect of fading, so that the traffic increases. In such a case, there is a problem that a call loss easily occurs. Since the required transmission quality is different depending on various services or media, if the same fading affects, even if the transmission quality is satisfied in one service, it will be different from other services. In some cases, the transmission quality cannot be satisfied. Also, when a plurality of information data under different transmission conditions, such as voice and image data, are multiplexed and transmitted, transmission cannot be performed unless a large number of multiplexed channels are used, and the frequency utilization efficiency is reduced. There is also a problem of causing a decrease.

Therefore, the present invention solves the above-mentioned conventional problems in multimedia communication, and requires data of various services and media requiring high transmission quality and a large transmission capacity. Provided is a spread spectrum modulation variable multiplex transmission apparatus which can multiplex information data having different transmission conditions, such as data, by using the same user using a plurality of channels and efficiently transmitting the data over a transmission path having the same band. It is intended to be.

[0011]

In order to achieve the above object, the present invention uses a transmitter capable of outputting a spread modulated signal in which a plurality of channels are multiplexed.
Alternatively, the transmission unit of the spread spectrum modulation multiplex transmission apparatus that transmits data on the same band transmission path by using a plurality of channels may include, for transmission information data, Transmission for setting the M-ary modulation value of data modulation and the M-ary modulation value of spread modulation in the transmission channel based on the transmission channel multi-level multiplexing number designation information identified by the designation information from the partner station received by the receiver. A channel control circuit and data for distributing the transmission information data in parallel to data of one or more channels in accordance with the number of multiplexed channels set by the transmission channel control circuit.
A data distributor, a data multi-level modulator for performing data modulation with the modulation multi-level number of data modulation set by the transmission channel control circuit for each transmission channel, and the transmission channel control circuit. Spread-spectrum multi-level modulation, in which the spread modulation rate is the same, the phase is synchronized, and the spread spectrum is spread using spread code data of a different spread code sequence for each transmission channel with the set multi-level number of spread modulation. And a multi-level number and a channel multiplex number of data modulation and spread modulation of a return transmission channel of a partner station, which are provided in at least one of the transmission channels and determined by a signal received by a receiving unit. A return transmission channel multi-level multiplexing number specification information adding circuit for adding specification information to transmission data; and a multiplexing circuit for multiplexing spread multi-level modulation signal output from each transmission channel. The channel control circuit is configured by a plurality of transmission data in accordance with the transmission channel multi-level multiplex number designation information, the channel multiplex number and the modulation multi-level number of data modulation and spread modulation in each transmission channel. It can be set in units of packets, such as a single slot or a frame composed of a plurality of the slots.

The transmission channel control circuit controls the channel amplitude variator for each packet to change the amplitude of the spread multi-level modulation signal for each channel. The output amplitude of the spread multi-level modulation signal is set. Further, a transmission information adding circuit for adding transmission channel identification information indicating the number of multiplexed channels of the transmission signal and the multi-level modulation levels of data modulation and spreading modulation of each transmission channel to the transmission data is provided. At least one of these channels is provided.

Furthermore, in the spread spectrum modulation multiplex transmission apparatus according to the present invention, the receiving section for demodulating the transmitted multiplexed signal of a plurality of channels includes: A signal-to-interference-noise-power-ratio calculation circuit for calculating an interference-noise-power ratio, and, based on the signal-to-interference-noise-power ratio calculated by the calculation circuit, an optimum number of multiplexed channels and data modulation and spreading in a return transmission channel of a partner station. A return transmission channel multilevel multiplexing number determination circuit that determines the modulation multilevel number of modulation and outputs the return transmission channel multilevel multiplexing number specifying information to specify them; and the return transmission channel multilevel multiplexing number specifying information. Are sequentially stored, and the number of multiplexed reception channels and each reception A reception multi-level multiplex number information memory for outputting information of the multi-level modulation number of the data modulation and the spread modulation of the channel to the reception channel control circuit; a channel multiplex number of the received spread spectrum multi-level modulation signal; A receiving channel control circuit for setting the modulation level of data modulation and spread modulation corresponding to the receiving channel based on output information from the receiving channel multilevel multiplexing number information memory; A spectrum despreading multilevel demodulator and a data multilevel demodulator for performing spectrum despreading and data demodulation for each reception channel in accordance with the modulation multilevel number set for each channel; and the reception channel control circuit. A data collector for converting demodulated data of each of the reception channels into serial data according to the set number of multiplexed channels; At least one channel is provided in at least one channel, and the return transmission channel multilevel multiplexing number designation information identification for identifying the own transmission station multilevel multiplexing number designation information sent from the partner station from the received signal and outputting to the transmission section Circuit, and demodulates received information data of a plurality of channels in units of packets such as a slot constituted by a plurality of transmission data or a frame constituted by a plurality of said slots. -Output as data.

Further, an interference noise power ratio with respect to the received signal calculated by the signal to interference noise power ratio calculation circuit;
Using a signal-to-interference power ratio calculated from a received signal of a past reception channel, a reception next-channel signal-to-interference noise power ratio estimation value calculation circuit that estimates and calculates a signal-to-interference noise power ratio of the next channel, The loopback transmission channel multi-level multiplexing number determination circuit is configured to output the loopback transmission channel multilevel multiplexing number specifying information of the partner station to the transmitting unit based on the reception next channel signal-to-interference noise power ratio estimation calculation value. I have. Furthermore, the number of multiplexed channels added to the transmission data by the transmission unit of the partner station and the number of modulation levels of data modulation and spread modulation of each channel in at least one channel among the plurality of reception channels. A reception channel identification circuit for identifying, from a received signal, multi-level multiplex number identification information indicating output information of the reception channel multi-level multiplex number information memory and a multiplex number from the reception channel identification circuit. Based on the value multiplex number identification information,
The number of multiplexed channels of the received spread spectrum multi-level modulation signal and the number of modulation levels of data modulation and spread modulation corresponding to each reception channel are set.

In such a spread spectrum modulation multiplex transmission apparatus according to the present invention, the transmission conditions of information data to be transmitted, propagation path fluctuations due to fading, etc., and inter-channel interference fluctuations due to increase / decrease in traffic etc. Therefore, it is possible to perform data transmission while changing the number of multiplexed channels and the number of modulation levels of the data multi-level modulator and the spread spectrum multi-level modulator for each of a plurality of channels in units of transmission packets and the like. Therefore, many information signals can be transmitted without deteriorating the error rate of transmission data. Therefore, it is possible to transmit information of various types of services and media with a sufficient quality, to improve the overall transmission capacity or throughput, and to improve the efficiency in the transmission path of the same band. Transmission.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the spread spectrum modulation multiplex transmission apparatus according to the present invention, data transmission and reception operations when transmission information data is multiplexed and transmitted using a plurality of channels will be described with reference to FIGS. 4 will be described. FIG. 1 is a block diagram [part 1] illustrating a configuration example of a transmission section of an embodiment of a spread spectrum modulation variable multiplex transmission apparatus according to an embodiment of the present invention. Here, the transmission information data 112 is converted into a parallel signal of the number of multiplexed channels corresponding to the required transmission conditions, required transmission capacity, propagation path fluctuation, and the like. Transmission channels (1) to (N) 11
It is assumed that channel multiplexing is performed using a corresponding number of transmission channels of 1 and transmission is performed.

As shown in FIG. 1, this transmitting section includes a number of channels (number of multiplexed channels) for distributing and multiplexing transmission information data 112, a multi-level modulation number of data modulation in each channel, and spread modulation. And a transmission channel control circuit 123 for setting the modulation multi-level number based on the transmission channel multi-level multiplexing number specification information 124 identified by the specification information from the partner station received by the receiving unit. Transmission information data 11 according to
And a data distributor 113 for distributing 2 in parallel to data of one or more channels, and a data multi-valued number of data modulation set by the transmission channel control circuit 123 for each channel. Data multi-level modulator 114 for performing modulation
And a multi-valued transmission channel for adding the multi-valued data modulation / spread spectrum modulation multi-value number and channel multiplexing designation information 116 to the transmission data determined by the signal received by the receiving unit. A spreading code of a spreading code sequence having the same spreading modulation speed, the same phase, and a different spreading code sequence for each channel, based on the modulation multi-value number of the spreading modulation set by the multiplexing number specifying information adding circuit 115 and the transmission channel control circuit 123. A spread coder 118 for outputting a signal; a spread spectrum multi-level modulator 117 for multiplying the spread code signal output from the spread coder 118 by the data multi-level modulated signal to spread the spectrum; And a multiplexing circuit 1 for multiplexing the output of the spread multi-level modulated signal 120 from each channel. Composed of one Tokyo.

Here, the data multi-level modulator 114, the spread spectrum multi-level modulator 117, and the channel amplitude variator 1
Reference numeral 19 denotes the transmission channels (1) to (N) 11 of the transmission modulation unit 110.
Although required for each channel, the loopback transmission channel multi-level multiplexing number specifying information adding circuit 115 specifies these when adding to one channel specified collectively or when adding to multiple channels. The configuration is provided only for the channel.

As described above, according to the present invention, the transmission channel multi-level multiplex number designation information 124 designated by the partner station is provided.
, The number of multiplexed channels of the transmission signal of the own station and the number of modulation levels of data modulation and spread modulation are set. Also, the return transmission channel multi-level multiplexing number specifying information adding circuit 115 specifies the number of channel multiplexing at the time of transmission by the other station, the number of modulation level of data modulation and spread modulation, and the number of return transmission channel multi-level multiplexing number specifying information. Is added to the transmission signal and transmitted.

Data of various services and media and transmission information data 112 having different required transmission conditions are input to the transmission unit configured as described above.
3 is supplied. In the transmission channel control circuit 123, a data distributor for distributing the transmission information data 112 corresponding to a plurality of channels in accordance with transmission channel multi-level multiplexing number designation information 124 supplied from a receiving unit described later. 113
To control the number of modulation levels of the data multi-level modulator 114, the spread coder 118, and the spread spectrum multi-level modulator 117 for each of a plurality of channels.

In accordance with the above control, the transmission information data 11
2 is distributed in parallel by a data distributor 113 to data corresponding to the transmission channels (1) to (N) 111 of the transmission modulator 110 and transferred to the data multi-level modulator 114 of each channel. The data is modulated according to the set modulation multi-level number.
Also, according to the return transmission channel multi-level multiplexing number designation information 116 which indicates the number of multiplexed channels and the number of modulation levels of the return transmission packet of the partner station, which are set from the receiving unit described later, these designated information are returned to the return transmission channel. The multi-level multiplexing number specifying information adding circuit 115 adds the data to the data modulation output. Here, when transmitting a signal as a packet, the designation information is added to the beginning of each packet or the like, and when the designation information is added to one or more channels that are designated collectively, The designated information is added by the loopback transmission channel multi-level multiplexed number designated information adding circuit 115 provided for the designated channel.

Next, the spread spectrum multi-level modulator 117 multiplies the code output from the spread coder 118 according to the set modulation multi-level number to obtain a spread spectrum multi-level signal. As the spread code output output from the spread encoder 118, different code sequences are used for each of the illustrated transmission channels (1) to (N) 111, and the spread code outputs of the respective channels have the same spread code rate. The code phase is synchronized. Since the same orthogonal code as in the above-described conventional example is used for these spread code sequences, if the code phases of the spread code sequences are synchronized, interference occurs between these multiple channels. do not do. The output amplitudes of these multi-channel spread multi-level signals are adjusted by a channel amplitude variable device 119 controlled by the transmission channel control circuit 123 to become a multi-channel transmission multi-level signal 120. And a transmission multiplex signal 122 is output.

Here, the variable amplitude of the channel output signal by the channel amplitude variable unit 119 is used for transmitting one information data by multiplexing a plurality of channels of different modulation multi-levels, or for controlling transmission power. Used. FIG.
FIG. 5 is a diagram showing an example of a case in which two pieces of information data are transmitted by multiplexing a plurality of channels of different modulation multilevels, where spread modulation has the same modulation multilevel and data modulation is (1) in FIG. As shown in FIG. 4, for example, regarding a packet transmitted by three-channel multiplexing of the BPSK modulation channel 710, (2) in FIG.
BPSK modulation channel 710 BPSK
The combined channel of [1] and BPSK [2] is set as one channel of QPSK [1] of the QPSK modulation channel 711, and B
It is assumed that PSK [3] is changed to multiplexing of two channels with one channel as it is and transmitted. In such a case,
For the purpose of equalizing the transmission errors of these two channels,
This can be coped with by making the amplitude of the BPSK [3] channel of the BPSK modulation １ ／ by the amplitude variable unit 119. Further, when the entire transmission output is changed by the transmission power control, it is possible to cope with the same increase / decrease in the amplitude by the amplitude variator 119 of each channel. Although not shown in FIG. 1, the transmission power control can also be performed by providing an amplitude variator on the output side of the multiplexing circuit 121 and performing amplitude variability on the transmission multiplexed signal 122. The transmission multiplex signal 122 output as described above is transmitted and received by the receiving unit.

FIG. 2 is a block diagram [part 1] illustrating an example of the configuration of a receiving section of an embodiment of the spread spectrum modulation multiplex transmission apparatus according to the present invention. As shown in the figure, the receiving unit is provided with a receiving demodulation unit 310 provided with a plurality of receiving channels (1) to (N) 311 corresponding to the transmission multiplexed signal transmitted from the transmitting unit in FIG. ing. Then, the received reception multiplexed signal 3 is input to the reception channels (1) to (N) 311.
21, a spectrum despreading multilevel demodulator 319 for despreading the spectrum using the multilevel signal of the spreading code supplied from the spreading encoder 320, and the multi-level multiplexing number specifying information of the local transmission channel of the own station from the received signal. An identification circuit 316 for specifying the number of return transmission channel multi-level multiplex numbers to be identified and a data multi-level demodulator 315 for controlling the modulation multi-level number for data demodulation by the reception channel control circuit 318 are provided. Here, the spectrum despread multi-level demodulator 319 and the data multi-level demodulator 315 are required for each of the plurality of reception channels (1) to (N) 311 of the reception demodulation unit 310 in the illustrated example. The loopback transmission channel multi-level multiplexing number designation information identification circuit 316 is used by the transmitting section to add the data to one channel specified collectively, or to add the data to a plurality of channels. A configuration is provided only for the channel.

Further, a reception channel control circuit 31 to be described later
8, a spread coder 320 in which the modulation multi-level number of the code output is varied, a signal-to-interference-noise-power ratio calculation circuit 322 for calculating the interference-noise-power ratio for the signal, A loopback transmission channel multilevel multiplexing number determination circuit 323 for determining the number of multilevel multiplexing of the transmission channel and outputting the specified information to the transmitting section, sequentially storing the loopback transmission channel multilevel multiplexing number specifying information 324, And a reception channel multilevel multiplexing number information memory 325 for outputting information on the modulation level of data modulation and spreading modulation of each channel to the reception channel control circuit 318. A reception channel control circuit 318 for setting a multi-level modulation number of data modulation and spread modulation, and reception channel data 3 from each of the reception channels (1) to (N) 311. 4 series de - collected data and received information de - de outputs the data 312 - data collector 313, are provided.

In the receiving unit configured as described above, the reception multiplexed signal 32
1 is input, and in the spectrum despreading multi-level demodulator 319, despreading is performed by multiplying the code output from the spreading encoder 320 in accordance with the set modulation multi-level number, thereby performing data modulation. The signal is returned. The data-modulated signal is supplied to the loopback transmission channel multilevel multiplexing number designation information identifying circuit 316, and the data modulation and spread modulation of each channel to be multiplexed with the channel multiplexing number of the loopback transmission channel of the own station. The modulation M-ary number is identified, and the transmission channel M-ary multiplex number designation information 317 is output to the transmission section. The return transmission channel M-ary multiplex number designation information sent from the partner station is transmitted to one or a plurality of channels designated collectively by the transmitter of the partner station. The specified receiving channel 31
1 return transmission channel M-ary multiplex number designation information identification circuit 3
At 16, the identification information is identified and supplied to the transmitting unit.

The data-modulated signal is also supplied to a signal-to-interference-plus-noise power ratio calculation circuit 322, and the signal-to-interference-plus-noise power ratio is calculated based on the whole or a part of the received signal of the packet to be modulated. Based on the calculated value, the loopback transmission channel multi-level multiplex number determination circuit 323 calculates the optimum channel multiplexing number and data modulation of the loopback transmission channel of the partner station corresponding to the propagation path fluctuation and traffic fluctuation. The multi-level modulation number of the spread modulation is determined, and the folded transmission channel multi-level multiplex number designation information 324 is output to the transmission unit and the reception channel multi-level multiplex number information memory 325.

Receiving channel multi-level multiplex number information memory 325
Stores sequentially the return transmission channel M-ary multiplex number designation information 324 and receives the setting information of the number of multiplexed channels and the modulation M-ary number of data modulation and spread modulation corresponding to the packet transmitted from the partner station. The signal is supplied to a channel control circuit 318. The reception channel control circuit 318 determines the number of modulation levels of the data multi-level demodulator 315, the spread coder 320 and the spectrum despreading multi-level demodulator 319 according to the supplied setting information. , Control is performed so as to match the modulation multi-level number corresponding to each of the plurality of channels multiplexed and transmitted by the transmission unit.

The data multi-level modulated signal output from spectrum despread multi-level demodulator 319 is further transferred to data multi-level demodulator 315 and received channel control circuit 318.
The data is demodulated according to the modulation multi-level number set by
Reception channel data 314 corresponding to the multiplexed transmission data of a plurality of channels is output from reception demodulation section 310, converted to serial data by data collector 313, and reception information data 312 is reproduced. Is done.

FIG. 3 is a diagram showing an example of a packet transmission timing operation between the stations A and B each having the transmitting section (FIG. 1) and the receiving section (FIG. 2). Here, each station is assumed to transmit data in a packet unit such as a slot composed of a plurality of transmission data or a frame composed of a plurality of the slots, as described above. Each packet is transmitted with the above-mentioned designation information (return transmission channel multi-level multiplex number designation information) added to the head portion. In FIG. 3, the horizontal axis is a time axis,
(A) shows the transmission data of the A station, (b) shows the reception data of the B station, (c) shows the transmission data of the B station, and (d) shows the reception data of the A station. Here, in the initial state, the number of multiplexed channels used for transmission of the information from the station A and the number of modulation levels of the data modulation and the spread modulation are set to an initial set value predetermined by the type of the data. Shall be

As shown in FIG. 3A, the station A transmits a transmission packet A1 having designation information and data a1, which is received by the station B as shown in FIG. 3B. In the return transmission channel multi-level multiplexing number designation information identifying circuit 316 in the receiving section of the station B, the transmission packet A1
Is extracted, and the transmission channel multi-level multiplexing number specification information 124 is supplied to the transmission channel control circuit 123 of the transmission unit. As a result, as shown in (c), the B station transmits the transmission packet B1 of its own station using the number of channels set by the transmission channel M-ary multiplex number designation information, and performs the data modulation and spread modulation of the set data modulation and spread modulation. Transmit with modulation multi-level number. Further, the signal-to-interference-noise-power ratio calculating circuit 322 in the receiving unit of the station B calculates a signal-to-interference-noise power ratio from the received signal of the received transmission packet A1, and performs the return transmission based on the calculation result and the like. The channel multi-level multiplexing number determination circuit 323 generates the return transmission channel multi-level multiplexing number designation information 324, stores it in the reception channel multi-level multiplexing number information memory 325, and returns the transmission channel multi-level multiplexing number of the transmitting section. It is supplied to the number designation information adding circuit 115. Thereby, as shown in (c),
The return transmission channel multi-level multiplex number designation information 116 is added to the transmission packet B1 transmitted by the station B and transmitted.

As shown in (d), this transmission packet B
1 is received by the station A, and based on the designation information extracted by the loopback transmission channel multi-level multiplexing number designation information identifying circuit 316 in the same manner as the reception section of the station A, Channel multiplexing number of the transmission packet A2 of
A modulation multi-level number of data modulation and spread modulation is set.
Further, the return transmission channel multi-level multiplex number determination circuit 32
3 to generate a multi-level multiplexing number designated for station B,
It is added to the transmission packet A2 and transmitted. The station B that has received the transmission packet A2 takes out the designation information stored in the transmission packet and sets it in the transmission channel control circuit 123 in the same manner as described above. The multiplex number designation information 324 is generated. At this time, the spread coder 320 and the data using the return transmission channel M-ary multiplex number designation information generated when the transmission packet A1 is received and stored in the reception channel M-ary multiplex number information memory 325 are used. The multi-level demodulator 315 and the data collector 313 are set.

As described above in detail, in this embodiment of the present invention, the optimum number of multiplexed channels and data modulation used by the partner station for transmission, based on the signal-to-interference noise power ratio of the received packet, etc. Then, the modulation multi-level number of the spread modulation is determined, and the designation information for designating these is transmitted to the partner station. Then, the other station sets the number of multiplexed channels used for transmission of the own station and the number of modulation levels of data modulation and spread modulation for each packet based on the transmitted specification information. Therefore, data transmission can be performed while finely changing transmission conditions in accordance with fluctuations in the propagation path due to fading, fluctuations in inter-channel interference due to increase / decrease in traffic, etc., thereby deteriorating the transmission data error rate. It is possible to transmit many information signals without the need.

Next, another embodiment of the spread spectrum modulation multiplex transmission apparatus of the present invention will be described. FIG.
FIG. 8 is a diagram illustrating a configuration example of another embodiment of the transmission unit. In this figure, 210 to 224 are the same components as 110 to 124 in FIG. 1, respectively.
As shown in this figure, the transmission unit of this embodiment is different from the configuration shown in FIG.
Transmission channel identification information, such as the number of multiplexed channels set by the user and the number of modulation levels of data modulation and spreading modulation.
In this configuration, a transmission channel identification information addition circuit 225 added to the data is added. The transmission channel identification information adding circuit 225 is, like the loop transmission channel multi-level multiplexing number specifying information adding circuit 215, one channel or a plurality of channels for specifying identification information of a plurality of transmission channels to be multiplexed at once. Is provided only for those designated channels.

In this way, when the condition of the propagation path to be transmitted is poor, for example, the receiving unit of the partner station transmits the return transmission channel multi-level multiplex number designation information designated by the partner station and the added transmission channel. Together with the identification information, it is possible to more accurately and accurately identify and demodulate the number of multiplexed channels of the received packet and the number of modulation levels of data modulation and spread modulation. Also, in response to the transmission channel multi-level multiplexing number designation information 224 designated by the partner station, when the own station wants to change the transmission conditions and transmit the data, the number of multiplexed transmission channels and the data -By transmitting data modulation and spread modulation identification information and transmitting, it is possible to change transmission conditions faster and more easily and more flexibly with changes in transmission data as well as fluctuations in the propagation path. Becomes

FIG. 6 is a block diagram showing a configuration example of another embodiment of the receiving section. In FIG.
425 is the same as 310 to 325 in FIG. The embodiment shown in this figure is different from the configuration shown in FIG. 2 in that the received next channel signal-to-interference is calculated by estimating and calculating the variation of the propagation path and traffic of the next channel, which is the timing of receiving. The noise power ratio estimation value calculation circuit 427 and transmission channel identification information such as the number of multiplexed channels and the multi-level modulation values of data modulation and spread modulation set by the transmission channel control circuit in the transmission section of the partner station are transmitted to the transmission data. In the case where the information is transmitted while being added to the data, a reception channel identification circuit 426 for identifying such information from the reception signal is added.

The reception next channel signal-to-interference noise power ratio estimation value calculation circuit 427 uses the data of the calculation value calculated by the signal-to-interference noise power ratio calculation circuit 422 by using an interpolation formula or the like, and Calculate the signal-to-interference-noise power ratio as an estimated value that predicts the propagation path fluctuation at the previous timing and the fluctuation of inter-channel interference due to increase or decrease in traffic, corresponding to the packet of the return transmission channel, and returns the estimated calculated value. This is supplied to the transmission channel M-ary multiplex number determination circuit 423. As described above, since the transmission condition of the return transmission channel is determined using the estimated calculated value, it is possible to accurately estimate the propagation path fluctuation such as fading and the traffic fluctuation at the previous timing. It becomes possible to determine the modulation variable condition of the transmission channel that is accurately adapted by the traffic fluctuation.

Further, as described in the block diagram [2] of the configuration example of the transmission unit in FIG. 5, the reception channel identification circuit 426 has the transmission channel identification information addition circuit 225 provided in the transmission unit of the partner station. When transmission channel identification information such as the number of multiplexed channels and the number of modulation levels of data modulation and spreading modulation is added to transmission data and transmitted, reception channels corresponding to a plurality of transmission channels to be multiplexed. At 411, the channel identification information is provided for one or more designated channels, and the channel identification information is identified from the received signal and supplied to the reception channel control circuit 426.

In this way, even if the condition of the propagation path to be transmitted is deteriorated, the added reception channel identification information and the information supplied from the reception channel multi-level multiplex number information memory 425 are combined. The received information data 412 can be demodulated by more accurately and accurately discriminating the number of multiplexed channels of the received packet and the number of modulation levels of data modulation and spread modulation. In addition, when the partner station wants to transmit after changing the transmission conditions for the multi-level multiplexing number of the return transmission channel specified by the own station, the changed transmission channel identification information is added together with the transmission condition change information. By transmitting, it becomes possible to change the transmission condition accompanying the change of the transmission data as well as the fluctuation of the propagation path more quickly and easily and more flexibly.

In the above-described embodiment, the return transmission channel multilevel multiplexing number designation information for specifying the return transmission condition of the partner station, and the transmission channel identification such as the channel multiplexing number and the modulation multilevel number of the transmission packet of the own station. Although the method of adding information to a transmission channel to be multiplexed and transmitted has been described, as another method, the above-described designation information is obtained by using a pilot channel or the like provided separately from a data channel to be multiplexed and transmitted. And transmitting identification information and acquiring such information from a pilot channel signal.

Further, in the transmission section shown in FIGS. 1 and 5, one transmission modulation section is provided for one transmission information data. However, the present invention is not limited to this. For transmission information data, a plurality of transmission modulators having a corresponding plurality of channels may be provided, and modulated multi-level signals from each transmission modulator may be multiplexed by a multiplexing circuit and transmitted. Further, data in which a plurality of pieces of transmission information data are distributed may be allocated to a plurality of transmission channels provided in an arbitrary number (for example, one) of transmission modulation sections, multiplexed, and transmitted. .

In the spread spectrum modulation variable multiplex transmission apparatus of the present invention described above, when transmitting transmission data requiring a high-quality propagation path or transmission data requiring real-time transmission, By increasing the number of channels to be multiplexed and reducing the number of modulation levels in the data multi-level modulator and the spread spectrum multi-level modulator, high-quality data transmission that is less affected by the propagation path can be realized. It becomes possible. When transmitting transmission data requiring a large transmission capacity, the number of channels to be multiplexed is increased, and the number of modulation levels in the data multi-level modulator and the spread spectrum multi-level modulator is increased. By doing so, large-capacity data transmission becomes possible.

In the present invention, the number of multiplexed channels and the number of modulation levels of the data multi-level modulator and the spread spectrum multi-level modulator in each channel can be variably set in packet units. It is possible to improve the transmission efficiency of the entire system. This content will be described with reference to FIG.

As the number of multi-level data modulation increases, the data
The error rate of the data deteriorates, and the reliability of transmission decreases. But,
In the case of packet transmission, the multivalued number of data modulation is increased when it is determined that the state of the propagation path is good, based on the calculated value or estimated calculated value of the signal-to-interference noise power ratio.
When switching from PSK modulation to QPSK modulation, assuming that the modulation symbol rate to be transmitted does not change, two channels of BPSK modulation can be transmitted by one channel of QPSK modulation to transmit the same amount of data. Will be. As a result, packet data can be transmitted with half the number of multiplexed channels, during which time interference with other users' transmission channels is reduced, and the apparent state of the propagation path is further improved. Therefore, it is possible to determine that the state of the propagation path is good and switch to QPSK modulation even in another channel where another user has transmitted by BPSK modulation. Alternatively, data packets of other channels used by the same user can be transmitted at the same transmission packet time.

For example, in FIG. 7, it is assumed that both user 1 and user 2 are transmitting the same spread multi-valued modulation data and the data modulation is a two-channel multiplexing of BPSK modulation. . At this time, if there is a fading fluctuation as shown in FIG. 7 between user 1 and user 2, as shown in (1), both user 1 and user 2 have the propagation path. When the condition is good, the two-channel multiplexing of BPSK modulation
Switch to one channel of SK modulation. As a result, the number of channels used becomes three. On the other hand, in the case of FIG. 7 (2) in which the control of the variable modulation as in the present invention is not performed, each of the users 3 and 4 is always transmitting by the two-channel multiplexing of the BPSK modulation, and Is 4 channels.

As described above, the state of the propagation path is constantly monitored,
When it is determined to be good, the number of channel multiplexes to be transmitted can be reduced by increasing the number of modulation levels in data modulation, and more information data can be transmitted in the same frequency band as a whole. And the transmission efficiency can be improved. If the transmission quality of the propagation path is degraded due to fading or the like, the problem can be dealt with by reducing the number of modulation levels of data modulation and increasing the number of multiplexed channels.

If the modulation multi-level number of the spread spectrum modulation is increased, the probability of erroneous synchronization of the spread code during demodulation increases. However, when the state of the propagation path is good, for example,
When switching from BPSK modulation to QPSK modulation,
Since the spreading code length is doubled, the number of usable channels can be doubled. As a result, another user or the same user can transmit new information data using the vacant channel by using the increased vacant channel. Moreover, since the spread modulation speed does not change,
The spreading band used for transmission does not change. Therefore,
The transmission quality of the propagation path is constantly monitored, and when it is determined that the state of the propagation path is good, the frequency can be used effectively by increasing the modulation multi-level number of the spread spectrum modulation. Further, when the transmission quality of the propagation path is deteriorated due to fading or the like, it can be dealt with by reducing the modulation multi-level number of the spread spectrum modulation.

The multi-level modulation scheme in the data multi-level modulator and the spread spectrum multi-level modulator is BPS.
Any of a phase modulation method such as K and QPSK, a frequency modulation method, and an amplitude phase modulation method such as 16QAM can be used.

[0049]

As described above, according to the present invention,
Using a plurality of channels as channels of the same user,
A large amount of information data can be transmitted without deteriorating the transmission data error rate, reducing inter-channel interference and reducing transmission data.
Therefore, it is possible to reduce the deterioration of the error rate of the data and improve the frequency use efficiency. If data can be transmitted at high speed with good propagation path conditions, the data multi-level modulators and the spread spectrum multi-level modulators of the channels to be multiplex-transmitted should be increased in number. If the channel multiplex number is reduced and transmission is performed and the state of the propagation path deteriorates, the modulation multi-level numbers of the data multi-level modulator and the spread spectrum multi-level modulator of the channel to be multiplexed and transmitted are reduced. hand,
By increasing the number of multiplexed channels, data can be transmitted without deteriorating the transmission quality. Therefore, in multimedia communication and the like, information data of various services and media capable of coping with higher transmission quality and larger transmission capacity, and information data having different required transmission conditions can be efficiently transmitted in the same band. Can be transmitted. Even when the transmission quality is degraded due to fading or the like, various services and services can be achieved by selecting a small number of modulation levels for each multiplexed transmission channel and increasing the number of multiplexed transmission channels. Media can be transmitted with sufficient quality, and the transmission capacity and throughput of the entire system can be further improved.

[Brief description of the drawings]

FIG. 1 is a block diagram [1] illustrating a configuration example of a transmission section of an embodiment of a spread spectrum modulation multiplex transmission apparatus according to the present invention.

FIG. 2 is a block diagram illustrating a configuration example of a receiving unit according to an embodiment of the spread spectrum modulation multiplex transmission apparatus of the present invention [part 1].

FIG. 3 is a diagram illustrating an example of a packet transmission / reception timing operation in the spread spectrum modulation multiplex transmission apparatus of the present invention.

FIG. 4 is a diagram illustrating an example of variable amplitude in channel multiplexing of different modulation multilevel numbers.

FIG. 5 is a block diagram [2] illustrating a configuration example of a transmission section of the embodiment of the spread spectrum modulation variable multiplex transmission apparatus according to the present invention.

FIG. 6 is a block diagram [2] illustrating a configuration example of a receiving unit of the embodiment of the spread spectrum modulation multiplex transmission apparatus according to the present invention.

FIG. 7 is a diagram showing the effect of the spread spectrum modulation variable multiplex transmission apparatus of the present invention.

FIG. 8 is a block diagram illustrating a configuration of a transmission unit of a conventional spread spectrum multiplex transmission apparatus.

FIG. 9 is a block diagram showing a configuration of a receiving section of a conventional spread spectrum multiplex transmission apparatus.

[Explanation of symbols]

110, 210, 510 Transmission modulators 111, 211, 511 Transmission channels (1) to (N) 112, 212, 512 Transmission information data 113, 213, 513 Data distributor 114, 214 Data multi-value Modulator (multi-level variable) 514 Data multi-level modulator 115, 215 Folded transmission channel multi-level multiplexing number designation information addition circuit 116, 216, 324, 424 Folded transmission channel multi-level multiplex number designation information 117, 217 Spread spectrum Multi-level modulator (multi-level variable) 515 Spread spectrum multi-level modulator 118, 218 Spreading coder of transmission section (multi-level variable) 516 Spreading coder of transmission section 119, 219 Channel amplitude variable section 120, 220, 517 Transmission Channel multi-level signal 121, 221, 518 Multiplexing circuit 122, 222, 519 Transmission multiplex signal 123, 223 Transmission channel Control circuit 124, 224, 317, 417 Transmission channel M-ary multiplex number designation information 225 Transmission channel identification information addition circuit 310, 410, 610 Reception demodulation units 311, 411, 611 Reception channels (1) to (N) 312, 412, 612 Received information data 313, 413, 613 Data collector 314, 414, 614 Received channel data 315, 415 Data multi-level demodulator (multi-level variable) 615 Data multi-level demodulator 316, 416 Return transmission channel M-ary multiplex number designation information identification circuit 318, 418 Reception channel control circuit 319, 419 Spectrum despreading multi-level demodulator (variable) 616 Spectrum de-spreading multi-level demodulator 320, 420 Spreading code of receiver (Multi-valued variable) 617 Spreading coder 321, 421, 618 of receiving section Received multiplex signal 322, 422 signal Interference noise power ratio calculation circuit 323, 423 Folded transmission channel M-ary multiplex number determination circuit 325, 425 Received channel M-ary multiplex number information memory 426 Reception channel identification circuit 427 Received next channel signal to interference noise power ratio estimation value calculation circuit 710 BPSK Modulation channel 711 QPSK modulation channel

Claims (6)

[Claims] A transmission unit capable of outputting a spread modulation signal obtained by multiplexing a plurality of channels is used.
Alternatively, the apparatus is a spread spectrum modulation multiplex transmission apparatus that performs transmission on a transmission path of the same band using a plurality of channels, wherein the transmission section distributes and multiplexes transmission information data by channel multiplexing. The number, the modulation level of data modulation and the modulation level of spreading modulation in each transmission channel are based on the transmission channel multilevel multiplexing number designation information identified by the designation information received from the partner station by the receiving unit. A transmission channel control circuit that sets the transmission information data in parallel according to the number of multiplexed channels set by the transmission channel control circuit; A data multi-level modulator for performing data modulation with the modulation level of data modulation set by the transmission channel control circuit for each transmission channel; The spread-spectrum multi-level number which is the same as the spread modulation rate, the phase is synchronized, and spreads using the spread code data of a different spread code sequence for each transmission channel. A modulator, provided on at least one of the transmission channels, and determined by a signal received by a receiving unit, a modulation multi-level number and a channel multiplex number of data modulation and spread modulation of a folded transmission channel of a partner station. And a multiplexing circuit for multiplexing spread multi-level modulation signal output from each transmission channel, wherein the transmission channel control circuit comprises: According to the transmission channel multilevel multiplexing number designation information, the number of channel multiplexing and the modulation level of data modulation and spread modulation in each transmission channel are transmitted to a plurality of transmission channels. A spread-spectrum modulation variable multiplex transmission apparatus, which can be set in units of packets, such as a slot composed of transmission data or a frame composed of a plurality of said slots. 2. The apparatus according to claim 1, further comprising a channel amplitude variable unit for varying an amplitude of the spread multi-level modulation signal for each channel, wherein the transmission channel control circuit controls the channel amplitude variable unit on a packet-by-packet basis for each channel. 2. The variable spread multiplex transmission apparatus according to claim 1, wherein an output amplitude of said spread multi-level modulation signal is set. 3. A transmission information adding circuit for adding transmission channel identification information indicating the number of multiplexed channels of a transmission signal and the number of modulation levels of data modulation and spread modulation of each transmission channel to transmission data. The spread spectrum modulation multiplex transmission apparatus according to claim 1, wherein the apparatus is provided in at least one of transmission channels. 4. A spread spectrum modulation multiplex transmission apparatus comprising a receiving section for demodulating a transmitted multiplex signal of a plurality of channels, wherein the receiving section comprises at least one channel among a plurality of receiving channels. A signal-to-interference-noise-power ratio calculating circuit for calculating an interference-noise-power ratio for a signal, and a signal-to-interference-noise-power ratio calculated by the calculation circuit,
Return transmission in which the optimum number of channel multiplexing and the number of modulation levels of data modulation and spreading modulation in the return transmission channel of the partner station are determined, and the return transmission channel multilevel multiplexing number specifying information for specifying them is output to the transmission section. A channel multi-level multiplexing number determination circuit, and the return transmission channel multi-level multiplexing number specifying information are sequentially stored. Based on the stored return transmission channel multi-level multiplexing number specifying information, the reception channel multiplexing number and the data of each reception channel are determined. -A multi-level multiplexing number information memory for outputting the multi-level modulation information of data modulation and spread modulation to the receiving channel control circuit; a multi-level multiplexing number of the received spread spectrum multi-level modulation signal; A receiving channel for setting a corresponding modulation level of data modulation and spreading modulation based on output information from the reception channel level multiplexing number information memory. A channel control circuit; a spectrum despreading multilevel demodulator and data for performing spectrum despreading and data demodulation for each reception channel according to the modulation level set for each reception channel by the reception channel control circuit; A multi-level demodulator; a data collector for converting demodulated data of each of the reception channels into serial data according to a channel multiplex number set by the reception channel control circuit; A folded transmission channel multi-level multiplexing number designation information identifying circuit provided in at least one channel or more and identifying the return transmission channel multi-level multiplexing number designation information of its own station sent from the partner station from the received signal and outputting to the transmission section And a plurality of channels in packet units such as a slot composed of a plurality of transmission data or a frame composed of the plurality of slots. Reception information data of - identical to data User - The demodulation de - spread spectrum modulation variable multiplex transmission apparatus and outputs as data. 5. A signal of a next channel using an interference noise power ratio for a received signal calculated by the signal to interference noise power ratio calculation circuit and a signal to interference power ratio calculated from a received signal of a past received channel. A reception next channel signal to interference noise power ratio estimation value calculation circuit for estimating and calculating an interference to noise power ratio; and the folded transmission channel multi-level multiplexing number determination circuit, the reception next channel signal to interference noise power ratio estimation calculation value. 5. The spread spectrum modulation variable multiplex transmission apparatus according to claim 4, wherein the multi-level multiplexing number designation information of the return transmission channel of the partner station is output to the transmitting unit based on the following equation. 6. The number of multiplexed channels added to transmission data by a transmission unit of a partner station to at least one channel among the plurality of reception channels, and the modulation factor of data modulation and spread modulation of each channel. A reception channel identification circuit that identifies multi-level multiplex number identification information indicating the number of values from a received signal, wherein the reception channel control circuit is configured to output from the reception channel multi-level multiplex number information memory and the reception channel identification circuit. Setting the number of multiplexed channels of the received spread spectrum multi-level modulation signal and the number of modulation levels of data modulation and spread modulation corresponding to each reception channel based on the multi-level multiplex number identification information. The said claim 4 or 5
A spread spectrum modulation variable multiplex transmission device according to claim 1.