JP3311252B2 - Transmission rate estimating apparatus and variable transmission rate communication system using the same - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an apparatus for estimating a transmission rate of a transmitted code in a digital communication system. Further, the present invention relates to a communication system using such a transmission rate estimation device.

[0002]

2. Description of the Related Art As the number of mobile phone subscribers increases, more effective use of frequency has become an issue.
One of the technologies for this effective use is CDMA (Code D
ivision Multiple Access). The CDMA cellular telephone system is, for example, a North American communication standard.
It is specified in TIA / EIA / IS-95.

[0003] In the CDMA communication system, four kinds of speeds can be used as a transmission speed for transmitting information bits. That is, 8.6 kbps, 4.0 kbps, 2.0 kbps, and 0.8 kbps
Different transmission rates are used. In practice, information bits are transmitted at a specific one of these four transmission rates. The information bits to be transmitted are divided into one frame every 20 msec. Then, it is transmitted for each frame. Therefore, at the above four transmission speeds, 172 bits and 80 bits are used, respectively.
bits, 40 bits, and 16 bits are included in one frame.

[0004] Of the above four transmission speeds, 8.6 kbps is
1 for each frame of information bits at 4.0 kbps
CRC bits of 2 bits and 8 bits are added. CRC bits are not added to frames of information bits of 2.0 kbps and 0.9 kbps. Then, an 8-bit tail bit is added to each frame of each transmission rate. At this point, the transmission speeds are 9.6kbps, 4.8kbps, 2.4kbps,
And it becomes 1.2kbps. Next, rate 1/2 convolutional coding is performed. After that, the same symbol is repeated twice when the transmission bit is 4.8 kbps information bits, four times when the transmission speed is 2.4 kbps information bits, and eight times when the transmission speed is 1.2 kbps information bits. Thus, the transmission speed of each information bit is unified to 19.2ksps. The information bits having a uniform transmission rate are then interleaved and then scrambled with a PN sequence.

[0005] Power control bits are further embedded in the scrambled information bits. In the CDMA communication system, one frame includes 384 symbols. 1
The frame is divided into 16 power control groups (hereinafter referred to as PCG). Therefore, one PCG includes 24 symbols. In 24 symbols of each PCG, power control bits of 2 symbols are arranged at random positions as power control information transmitted from the base station to the mobile station. At this time, the symbol originally located at this position is lost. The position where the power control bits are arranged is defined by the position of the first symbol of the two symbols of the power control bits. This position can take 16 types of positions based on 4 bits extracted from the PN sequence described above. Since one power control group is composed of 24 symbols, the power control bits are allocated to the 17th symbol from the head and are not allocated to the 18th to 24th symbols. The information bits in which the power control bits are embedded are spread with a Walsh sequence and a pilot PN sequence. And QPS
It is K-modulated and transmitted to the mobile station.

[0006]

A mobile station receives a signal transmitted from a base station. This received signal is QPS
It is K demodulated and despread with a Walsh sequence and a pilot PN sequence. Further, the power control bit is extracted. At the position where the power control bit has been extracted, “0” is embedded as there is no information. As a result, 19.2
A received symbol sequence of ksps is obtained. Next, the received symbol sequence is decoded, and the CRC is further checked. The received signal is a convolutionally coded signal, and for example, Viterbi decoding is used for decoding. Here, the mobile station cannot determine the transmission speed of the received signal at first. Therefore, it is necessary to estimate the transmission speed. That is, it is necessary to quickly estimate which of the four transmission rates is the transmission rate of the actually received signal.

[0007]

According to an embodiment of the present invention, a receiver has a plurality of accumulators connected in series. The accumulator outputs a signal obtained by accumulating the received signal for each predetermined band. These are each provided to a power meter. The output result output from each power measuring device is given to a transmission rate determiner,
Here, the actual transmission speed is determined.

In another aspect of the invention, a receiver has a plurality of accumulators connected in series. The accumulator outputs a signal obtained by accumulating the received signal for each predetermined band. These are each provided to a power meter. The receiver further measures the SN ratio of the received signal. The measured S / N ratio and the output result output from each power meter are:
It is provided to a transmission rate determiner, where the actual transmission rate is determined.

[0009] In still another embodiment of the present invention, the transmitter selects a transmission rate from among a plurality of predetermined transmission rates.
A digital signal is transmitted at a predetermined speed. The receiver receives this digital signal and preliminarily extracts some speeds from a plurality of transmission speeds. The decoding quality is evaluated for each of the extracted rates, and the transmission rate is finally estimated based on the result.

In still another embodiment of the present invention, the transmitter transmits a digital signal at a predetermined speed from among a plurality of predetermined transmission speeds. The receiver receives this digital signal and measures the SN ratio for each of the predetermined transmission rates. Then, the decoding quality is evaluated for each of the measurement results, and the transmission rate is finally estimated based on the evaluation results.

[0011]

FIG. 1 shows a CDMA communication system according to the present invention. This system includes a transmitter Tx and a receiver Rx. This system supports 8.6kbps, 4.0kbps, 2.0kbps, and 0.9kbps as described above.
Are used. CRC bit and tail bit are added to this, 9.6kbps, 4.8kbps, 2.4kbp
s, and 1.2 kbps as described above. The transmission signal S thus generated is input to the convolutional encoder 3 of the transmitter Tx. The convolutional encoder 3 performs convolutional encoding on the transmission signal S at a rate of 1/2. This doubles the transmission speed to 19.2ksps, 9.6ksps, and 4.8, respectively.
ksps, 2.4ksps. The convolutionally encoded transmission signal S is input to the repetition unit 4.

The repetition unit 4 unifies the transmission speed to 19.2 ksps. That is, the loopback unit 4 does not repeat when the transmission speed of the input information bits is 8.6 kbps (19.2 ksps). However, twice for information bits of 4.0 kbps (9.6 ksps) and four for information bits of 2.0 kbps (4.8 ksps).
Times, and 8 for 0.8kbps (2.4ksps) information bits
Times, the same symbol is output repeatedly. This output is scrambled with a PN sequence after being interleaved. Then the power control bits are embedded.

The output of the repetition unit 4 is provided to a spread spectrum unit 5. The spread spectrum unit 5 spreads the spectrum of the transmission signal and supplies the spread signal to the digital modulation unit 6.
The digital modulator 6 converts the given transmission signal into a QPSK signal.
(Quadrature phase shift keying) The signal thus modulated is transmitted from the antenna 71.

The receiver Rx1 receives a signal arriving from the transmitter Tx via the antenna 72. The received signal received by the antenna 72 is input to the digital demodulator 8. Here, the received signal is QPSK demodulated. This received signal is input to spectrum despreading section 9. In spectrum despreading section 9, the received signal is despread in spectrum. Next, it is despread with a PN sequence and deinterleaved. Thus, a received symbol is obtained.

The received symbols are input to the integration processing unit 10 and are also input to the transmission rate estimating device 12 at the same time. In the transmission rate estimation device 12, the transmission rate is estimated, and the processing in the integration processing unit 10 and the convolution decoding unit 11 is performed based on the transmission rate. That is, the received symbol of 19.2 ksps provided from the spectrum despreading unit 9 is integrated by the integration processing unit 10 based on the estimated transmission rate.

Next, the convolution decoding unit 11 decodes the information bit sequence based on the symbols integrated by the integration processing unit 10. The length of this information bit sequence is based on the transmission rate estimated by the transmission rate estimating unit 12. For the decoding performed by the convolutional decoding unit 11, a method such as Viterbi decoding is used. The convolution decoding unit 11 also checks the CRC. When interleaving is performed in the transmitter Tx, deinterleaving is performed after despreading is performed in the spectrum despreading unit 9.

Hereinafter, the processing performed by the integration processing unit 10 will be described. The integration processing unit 10 integrates the symbols repeated by the transmitter Tx, and converts the symbol sequence having a length corresponding to the transmission rate estimated by the transmission rate estimation unit 12 to the convolution decoding unit 1.
Feed to 1. Specifically, the following processing is performed.
When the estimated transmission rate is ２, the integration processing unit 10
Is represented by the following equation (1).

(Equation 1)

Similarly, when the transmission speed is 1/4 and 1/8, they are expressed by equations (2) and (3), respectively.

(Equation 2)

(Equation 3)

When the transmission rate is 1, the integration processing section 10 does not perform any processing.

Next, the detailed configuration and operation of the transmission rate estimating unit 12 will be described with reference to FIG. The received symbol output from spectrum despreading section 9 is provided to terminal 15. This received symbol is provided to the first received power measuring device 19 and at the same time to the first accumulator 16. The output of the first accumulator 16 is provided to the second power meter 20 and the second accumulator 17. The output of the second accumulator 17 is provided to the third power measuring device 21 and the third accumulator 18. The output of the third accumulator 18 is provided to a fourth power meter 22. Each accumulator is connected in series. Therefore, these accumulators limit the band of the received sample value to generate a plurality of band-limited signals. Further, each power measuring device obtains the average power of the output signal (band-limited signal) of each accumulator. The outputs of these power meters are provided to a transmission rate estimator 23. The transmission rate estimator 23 estimates the transmission rate of the code inserted in the received signal based on the average power obtained by the power measuring device. The estimated transmission rate is output from terminal 24 to integration processing section 10 and convolution decoding section 11.

The terminal 15 has a constant speed (for example, 19.2 ks).
The received symbol is input in ps). Here, the sampling period is 1, and the transmission speed of the transmission code is 1, 1/2, 1 /.
Assume that it is either 4 or 1/8. Therefore, when the transmission rate is 1/2, the transmission is performed twice and when the transmission rate is 1/4.
4 times if the transmission rate is 8 and 8 if the transmission rate is 1/8.
Each time, a received symbol in which the same transmission code is repeated is input. Here, the transmission code forms a frame,
The length of one frame is N sample periods. This frame length is defined by time and is constant regardless of the transmission speed. As a result, the number of codes included in one frame depends on the transmission speed. That is, the code of N when the transmission rate is 1, N / 2 when the transmission rate is 1/2, N / 4 when the transmission rate is 1/4, and N / 8 when the transmission rate is 1/8, It is included in one frame. Here, N is an integer multiple of 8.

The received symbol provided to terminal 15 is provided to first accumulator 16. This first accumulator 16
Adds two samples to each input sample. That is, if the input signal is x (n) [n = 1 to N],
The output a2 (i) of the first accumulator 16 is represented by the following equations.

(Equation 4)

The second accumulator 17 and the third accumulator 1
8 also adds the input samples by two samples, similarly to the first accumulator 16. That is, the output of each accumulator is represented by the following equation.

(Equation 5)

(Equation 6)

In this embodiment, received symbols are processed for each frame. For this reason, the first accumulator 16 reads N signals and outputs N / 2 signals. Similarly, the second accumulator 17 reads N / 2 signals and outputs N / 4 signals. And the third
Accumulator 18 reads N / 4 signals and outputs N / 8 signals.

Each power measuring device obtains an average power of one frame period for each of the received symbols supplied from the terminal 15 and the output signal supplied from each accumulator. The average power is specifically calculated based on the following equation. That is, the input sample sequence is defined as x (n) [n = 1 to
N], the output of each power meter is represented by the following equation.

(Equation 7)

(Equation 8)

(Equation 9)

(Equation 10)

Each of the power measuring devices 19, 20, 21,
22, the average power for one frame period based on the above equation
p5, p6, p7, p8 are measured. This measurement result is supplied to the transmission rate determiner 23. The transmission rate determiner 23 determines the transmission rate based on the given average powers p5, p6, p7 and p8. The estimation algorithm in the transmission rate determiner 23 is shown in FIG. In an ideal state, there is a relationship shown in FIG. 4 among the average powers p5, p6, p7, and p8.

Hereinafter, the algorithm for determining the transmission rate in the transmission rate determiner 23 will be described in detail with reference to FIG. The transmission rate determiner 23 calculates the ratio p8 / p5 of the average powers p5 and p8.
Then, the transmission rate is determined using the predetermined thresholds th1, th2, and th3. In this example, the power measuring devices 20 and 21 in FIG. 2 can be omitted. In addition, considering each of the threshold values shown in FIG. 4, th1 = 3/4 and th2 = 3
/ 8 and th3 = 3/16.

In step S1 of FIG. 3, the magnitude of p8 / p5 and the threshold value th1 are determined. If p8 / p5 is larger than the threshold th1, it is determined that the transmission rate is １ ／.
If p8 / p5 is smaller than threshold value th1, step S
Proceed to 2. In step S2, p8 / p5 and threshold value th2
And judge the size. If p8 / p5 is larger than the threshold value th2, it is determined that the transmission rate is １ ／. If p8 / p5 is smaller than the threshold value th2, the process proceeds to step 3.
In step S3, the magnitude of p8 / p5 and the threshold th3 is determined. If p8 / p5 is greater than threshold th3,
It is determined that the transmission rate = １ ／. If p8 / p5 is smaller than the threshold th3, it is determined that the transmission rate = 1.

In the above equations (7) to (10), 1 / N is multiplied. However, when the determination is made based on the ratio of the output values of the respective power measuring devices as described above, 1 / N may be omitted because they are offset each other. X ² (n), a2 ²
(i), a3 ² (j) and a4 ² (k) also take absolute values, and the square calculation can be omitted.

The transmission rate determiner 23 can use another algorithm. Here, a method of estimating the transmission rate using the distance between the measured power train and the four power trains shown in FIG. 4 will be described. Specifically, 4 (kinds)
Is represented by the following equations.

[Equation 11]

(Equation 12)

(Equation 13)

[Equation 14]

The transmission path determiner 23 calculates d1 to d4 according to the above equations, and selects the smallest value from them.
In an ideal state, the smallest value is 0. If the smallest value is d1, the transmission rate is determined to be 1. If the smallest value is d2, the transmission speed is determined to be 1/2. If the smallest value is d3, the transmission rate is determined to be 1/4. If the smallest value is d4, the transmission rate is determined to be 1/8.

As described above, the transmission rate is determined based on the power of the signal passing through each band limiting unit. Therefore, the transmission rate can be estimated without using a method such as a CRC check. In FIG. 1 described above, the functions constituting the present invention are represented by blocks, and each function is represented by individual hardware. However, it can also be realized as a software function using a DSP or the like. The band limiting means may be any as long as it limits the band of the received signal. As an example, FIR
A digital filter such as a digital filter or IIR may be used.

FIG. 5 is a block diagram showing still another configuration of the transmission rate estimator. In the configuration of the transmission rate estimator 121 shown in FIG. 5, the transmission path estimator 1 shown in FIG.
The same parts as in FIG. 2 are denoted by the same reference numerals, and detailed description is omitted. In this configuration, by estimating the power density of noise, the transmission rate is reliably estimated even when the received signal includes noise. To this end (to achieve the purpose), a subtractor 32 is added. The output of the first power measuring device 19 is input to the subtractor 32. The output of the second power measuring device 20 is input to the subtractor 32 and the transmission rate determiner 23. The output of the subtracter 32 is also input to the transmission rate determiner 23. The transmission rate determiner 23 estimates the transmission rate based on the average power obtained by the individual power measuring devices and the power density of the noise obtained by the subtractor 32.

The subtracter 32 subtracts the average power measured by the second power measuring device 20 from the average power measured by the first power measuring device 19. This subtraction value p11 means the power density of noise when the transmission speed is assumed to be less than 1. This value p11 is supplied to the transmission rate determiner 23 together with the output values of the second, third, and fourth power meters. In the transmission rate determiner 23, each average power p6,
The transmission rate is estimated based on p7, p8, and the subtraction value p11. This estimation operation will be described with reference to FIG.

In the algorithm shown in FIG. 6, the transmission rate is determined using the noise power density p11, the ratio p8 / p6 between the average powers p6 and p8, and predetermined thresholds th4, th5, and th6. In this example, the power measuring device 21 in FIG. 5 can be omitted. Note that each threshold value is, for example, th4 = p5 / 4, th5 = 3/4, th6 = 3 in consideration of the relationship shown in FIG.
/ 8.

In step S11 of FIG.
The magnitude of the result of 1 and the threshold value th4 is determined. If the result of p6-p11 is smaller than the threshold th4, the transmission rate is 1
Is determined. If the result of p6-p11 is larger than the threshold value th4, the process proceeds to step S12. In step S12, the magnitude of p8 / p6 and the threshold th5 is determined. p8 / p
When 6 is larger than the threshold th5, the transmission rate = 1 /
8 is determined. If p8 / p6 is smaller than the threshold th5, the process proceeds to step S13. In step S13, the magnitude of p8 / p6 and the threshold th6 is determined. When p8 / p6 is larger than the threshold th6, the transmission rate = 1/4
Is determined. If p8 / p6 is smaller than the threshold value th6, it is determined that the transmission rate is 1/2. Thus, the transmission rate can be correctly estimated even in a state where white noise is added.

Next, still another configuration of the transmission path estimator will be described. FIG. 7 is a block diagram showing the configuration of the transmission rate estimator 122. The transmission path estimator 12 shown in FIG.
The same parts as those described above are denoted by the same reference numerals, and detailed description thereof will be omitted. With this configuration, even when the received signal does not turn white, the transmission rate can be estimated well. To this end (to achieve the purpose), a signal selector 71 is added.
The received symbol input to terminal 15 is first input to signal selector 71. The signal selector 71 supplies a valid signal from the samples of the received signal to the first accumulator 24 and the power meter 19. In order to remove the power control bit from the received signal in the transmission selection circuit, the signal selector 71 preferably has a flip-flop or a switching element. When a flip-flop is used, no clock is input where the power control bit is located in the input signal. This removes the power control bit. When a switching element is used, the switch is turned off at the position where the power control bit is located in the input signal. This removes the power control bit. In practice, it is difficult to locate the power control bits. Therefore, if all positions where the power control bit can enter are removed, the processing becomes simple.

FIG. 8 shows one frame of a received signal in the CDMA system. As described above, one frame includes 384 symbols. In one frame shown in FIG. 8, a shaded portion is a portion into which a power control bit can enter. On the other hand, the white part in FIG. 8 is a part where the power control bit cannot enter. Specifically, the signal selector 71 supplies only the symbols in the white portions to the first accumulator 24 and the power measuring device 19. In this case, the symbol output from the signal selector 71 has no periodicity, and its spectrum can be regarded as white. The transmission rate estimator 23 estimates the transmission rate based on the average powers p5, p6, p7, and p8. This estimation operation will be described with reference to FIG.

In the algorithm shown in FIG. 9, the transmission rate is determined by using the average powers p5, p6, p7, and p8 and predetermined thresholds th7, th8, and th9. The threshold values th7, th8, and th9 are set as follows.

When the transmission rate is 1, the spectrum of the received signal has a waveform as shown in FIG. That is, the noise band is equal to the signal band. In this case, when the output p5 of the first power measuring device 19 and the output p6 of the second power measuring device 20 are compared, p6 is substantially equal to p5.
/ 2. That is, (2p6-p5) can be regarded as substantially zero. On the other hand, when the transmission rate is １ ／, the signal band is half of the noise band. That is, the spectrum of the received signal has a waveform as shown in FIG. In this case, (2p6-p5) means that the transmission rate is 1
/ 2 can be regarded as the signal power. Therefore, ideally, if (2p6-p5) is 0, the transmission rate can be determined to be 1; if (2p6-p5) is not 0, the transmission rate can be determined to be 1/2. However, actually, (2p6-p5) does not become 0 even if the transmission speed is 1 due to the influence of transmission line noise or the like. Therefore, the threshold value th7 at which the transmission rate 1 and the transmission rate ２ can be distinguished from each other is determined by an experiment, a computer simulation, or the like. Similarly, the threshold value th8 is set in consideration of (2p7-p6), and the threshold value th9 is set in consideration of (2p8-p7). The transmission rate is determined based on these thresholds.

In step S21 of FIG. 9, (2p6-
The magnitude of the result of p5) and the threshold value th7 are determined. (2p6-
If the result of p5) is equal to or smaller than the threshold th7, the transmission rate is determined to be 1. If the result of (2p6-p5) is larger than the threshold th7, the process proceeds to step S22. In step S22, the magnitude of the result of (2p7-p6) and the threshold value th8 is determined. If (2p7−p6) is smaller than the threshold th8, the transmission rate is determined to be １ ／. (2p7-
If p6) is greater than the threshold value th8, step S
Proceed to 23. In step S23, the magnitude of the result of (2p8-p7) and the threshold value th9 is determined. (2p8-p7)
Is smaller than the threshold th9, the transmission rate becomes 1 /
4 is determined. If (2p8−p7) is larger than the threshold th6, the transmission rate is determined to be ８.

As described above, only the valid received signal samples are selected by the signal selector, and the transmission rate is estimated. Since the received signal samples output from the signal selector have no periodicity, the spectrum of the received signal can be regarded as white. Therefore, the ability to estimate the transmission rate can be improved. Also, to select only valid received signals,
The amount of calculation will be greatly reduced. In the above description, the power control bits are removed by the signal selector 71, but other signals may be removed.

Hereinafter, another embodiment of the present invention will be described. The system in this embodiment includes a transmitter Tx and a receiver Rx2. The configuration of the transmitter Tx is the same as that shown in FIG. Also, for the receiver Rx2, the same parts as those of the receiver Rx1 shown in FIG. Hereinafter, the configuration of the receiver Rx2 will be described with reference to FIG.

The received signal received by the antenna 72 is input to the digital demodulator 8. The output of the digital demodulator 8 is input to the spectrum despreading unit 9. The output of the spectrum despreading unit 9 is a received symbol of 19.2 ksps. This received symbol is temporarily stored in the memory 40.
The received symbols read out from the memory 40 are input to the integration processing unit 10 and also to an S / N estimation unit 41 described later.
Is also entered. The S / N estimation unit 41 estimates the S / N ratio by an algorithm described later. Then, the estimated S / N ratio is input to the transmission rate estimation unit 42. The transmission rate estimating unit 42 estimates the transmission rate.
Then, processing in the integration processing unit 10 and the convolution decoding unit 11 is performed based on the estimated transmission speed.

The received symbols input to integration processing section 10 are provided (estimated) from transmission rate estimation section 42.
Integration is based on the transmission rate. Then, it is provided to the convolution decoding unit 11. The convolution decoding unit 11 decodes the convolutional code by a method such as Viterbi decoding,
An RC check is performed. When interleaving is performed by the transmitter Tx, deinterleaving is performed after the signal is despread by the spectrum despreading unit 9.

Hereinafter, the processing performed by the S / N estimating unit 41 will be described. First, the S / N estimator 41 calculates 19.2 kHz,
Powers P21, P22, P24, and P28 included in four types of bands of 9.6 kHz, 4.8 kHz, and 2.4 kHz are calculated, respectively. Specifically, this is performed as in the following equation. That is, if the signal input to the S / N estimation unit 41 is x (n) [n = 1 to N], this signal is 1
It has a 9.2 kHz band. For this reason, the power P21 included in the 19.2 kHz band is as shown in equation (15).

(Equation 15)

When x (n) is integrated every two samples, this band becomes half. Therefore, power P22 included in the band of 9.6 kHz is expressed by equation (16).

(Equation 16)

Similarly, the power included in the 4.8 kHz band
P24 and power P28 included in the 2.4 kHz band are expressed by equations (17) and (18), respectively.

[Equation 17]

(Equation 18)

The S / N estimating unit 41 then calculates P21, P22, P2
4. Based on P28, calculate the S / N ratio for each transmission rate. Assuming that the transmission rate is 1/2, 1/4 or 1/8, the S / N ratios are SNR2, SNR4 and SN, respectively.
If R8, it is represented by the following equations.

[Equation 19]

(Equation 20)

(Equation 21)

The S / N estimator 41 calculates the estimated S / N ratio SN
R2, SNR4, and SNR8 are supplied to the transmission rate estimating unit 42.

The transmission rate estimating section 42 estimates the transmission rate according to the algorithm shown in FIG. Where SN
Rmin and SNRmax are the minimum and maximum values of SNR2, SNR4, and SNR8, respectively. Th10 is a predetermined threshold value. In th10, a value that maximizes the probability of correctly estimating the transmission rate is determined by experiment or computer simulation, and set to that value. In step S31 of FIG. 11, it is determined whether or not the minimum value of the S / N ratio is smaller than a threshold th. If the minimum value of the S / N ratio is smaller than the threshold th10, the transmission rate is determined to be 1. S / N
If the minimum value of the ratio is larger than the threshold th10, the process proceeds to step S32. In step S32, if the maximum value of the S / N ratio is equal to SNR2, the transmission rate is determined to be 1/2.
Similarly, in step S33, the maximum value of the S / N ratio is
If it is equal to SNR4, the transmission rate is determined to be 1/4. In step S34, if the maximum value of the S / N ratio is equal to SNR8, the transmission rate is determined to be 1/8. As described above, the transmission rate is estimated before performing the convolutional decoding. Only the information bit sequence of the estimated transmission rate is decoded. As a result,
The amount of processing required for convolutional decoding can be reduced.

FIG. 13 shows still another embodiment of the receiver according to the present invention. The receiver Rx3 narrows down to a plurality of transmission rate candidates before convolutional decoding, and finally specifies the transmission rate based on the decoding quality after decoding. That is, in FIG. 13, a transmission rate preliminary estimation unit 43 is connected to the subsequent stage of the S / N ratio estimation unit 41. The transmission rate preliminary estimation unit 43 selects a plurality of candidates from the transmission rates that can be transmitted based on the S / N ratio estimated by the S / N ratio estimation unit 41.

FIG. 14 shows a processing algorithm in the transmission rate preliminary estimation unit 43. For the sake of simplicity, it is assumed that the transmission rate preliminary estimation unit 43 estimates two transmission rate candidates. Also, the following three combinations of candidates are provided. (a) SUB2: Transmission speed 1 or 1/2 (b) SUB4: Transmission speed 1 or 1/4 (c) SUB8: Transmission speed 1 or 1/8

In step S41 of FIG. 14, S / N
If the maximum value of the ratio is equal to SNR2, set the transmission rate to 1 or 1 /
2 (SUB2) is determined. Similarly, in step S42,
If the maximum value of the S / N ratio is equal to SNR4, the transmission rate is determined to be 1 or 1/4 (SUB4). In step S43,
If the maximum value of the S / N ratio is equal to SNR8, the transmission rate is determined to be 1 or 1/8 (SUB8). As described above, the transmission rate preliminary estimation unit 43 does not determine the final transmission rate, but narrows down to two types of candidates.

The transmission rate (in this case, 2) of the candidate selected by the transmission rate preliminary estimation section 43 is supplied to the integration processing section 10, the convolutional decoding section 11, the decoding quality judgment section 44, and the transmission rate judgment section 42. . The processing in the integration processing unit 10 and the convolution decoding unit 11 is performed based on each of the estimated plurality of transmission rates. Therefore, the convolution decoding unit 11 supplies a plurality of outputs to the decoding quality judgment unit 44 and the memory 45. The memory 45 stores these outputs. For example, the transmission rate preliminary estimation unit 43
Is selected, the information bits decoded assuming that the transmission rate is 1 and the information bits decoded assuming that the transmission rate is 1/2 are stored in the memory 45.

The decoding quality determining section 44 determines the quality of the convolutional decoding based on the information bits after the convolutional decoding. In order to determine the decoding quality, for example, a CRC check is performed. In a CDMA system, CRC bits are added to information bits of transmission rates 1 and 1/2. However, CRC bits are not added to information bits whose transmission rates are 1/4 and 1/8.
In this case, the decoding quality may be determined based on the final metric at the time of Viterbi decoding, and may be used in place of the error detection result. Also, the decoding quality may be determined by re-convolutionally encoding the information bits and comparing this with the symbol before decoding. Alternatively, these methods may be combined.
In this way, any method may be used as long as the quality of the decoded information bits is determined. As described above, a plurality of transmission rates are input to the decoding quality determination unit 44. Therefore, the decoding quality determination unit 44 determines the decoding quality for each of these.

The decoding results (plurality) of the decoding quality judging section 44 are output to the transmission rate estimating section 42. Transmission speed estimation unit 4
In 2, the transmission rate is estimated based on the transmission rate candidates estimated by the transmission rate preliminary estimation section 43 and the convolutional decoding quality determined by the decoding quality determination section 44.
Here, the decoding quality corresponding to the transmission rate 1 is Q1, the decoding quality corresponding to the transmission rate 1/2 is Q2, the decoding quality corresponding to the transmission rate 1/4 is Q4, and the decoding corresponding to the transmission rate 1/2. Quality is Q8. In addition, each decoding quality is "GOOD"
Alternatively, it can be determined as "BAD".

The transmission rate estimating section 42 estimates the transmission rate based on the algorithm shown in FIG. If the decoding quality Q1 is determined to be “GOOD” in step S51 of FIG. 15, the transmission rate is determined to be 1. Step S
In 52, when the transmission rate preliminary estimation unit 43 selects SUB2 and the decoding quality Q2 is determined to be "GOOD", the transmission rate is determined to be 1/2. Similarly, a transmission rate of 1/4 to 1/8 is determined. In any case, if the decoding quality is not determined to be "GOOD", it is determined that the frame has been lost.

Then, information bits corresponding to the final transmission rate determined by the transmission rate estimating section 42 are output from the memory 45. As described above, the transmission rate is preliminarily estimated before performing convolutional decoding, and the transmission rate is estimated in consideration of the decoding quality determined after decoding. For this reason, the estimation accuracy of the transmission rate is further improved as compared with the receiver shown in FIG. Also,
Since only the presumed transmission rate candidates are convolutionally decoded, the processing amount required for convolutional decoding can be reduced.

FIG. 16 shows still another embodiment of the receiver according to the present invention. In this receiver Rx4, the transmission rate is not estimated before convolutional decoding, and the decoding quality and S / N
The transmission rate is estimated based on the ratio.

In the receiver Rx4, the output of the memory 40 is given to the S / N ratio estimating unit 41 and the integration processing unit 10. The output of the integration processing unit 10 is provided to the convolution decoding unit 11. The output of the convolution decoding unit 11 and the output of the S / N ratio estimation unit 41 are provided to a transmission rate estimation unit 42.

Integrator 10 and convolution decoder 11
Performs processing for all expected transmission rates. Then, the decoded information bits are output to the decoding quality judgment section 42 and stored in the memory 45. That is, the memory 45
Stores information bits in all cases assuming transmission rates of 1, 1/2, 1/4, and 1/8. Here, the decoding quality decoded assuming the transmission rate of 1 is Q1, the decoding quality decoded assuming the transmission rate of 1/2 is Q2, similarly, the transmission quality of the transmission rate of 1/4 is Q3, and the transmission rate is 1 The transmission quality of / 4 is defined as Q4.

The decoding quality judgment section 42 judges decoding qualities Q1 to Q4 for each of the decoded information bits.
The result of the determination is output to the transmission rate estimating unit 42. The transmission rate estimator 42 estimates the transmission rate based on the signal-to-noise ratio estimated by the S / N ratio estimator 41 and the decoding quality determination result determined by the decoding quality determiner 44. Next, information bits corresponding to the estimated transmission speed are output from the memory 45.

FIG. 17 shows the processing performed by the transmission rate estimating section 42. In step S61, the decoding quality Q1 is "GOOD"
Is determined, the transmission rate is determined to be 1.
In step S62, it is determined whether or not the decoding quality Q2 is "GOOD". When the decoding quality Q2 is "GOOD", the process proceeds to step S63, and when the decoding quality Q2 is not "GOOD", the process proceeds to step S64. In step S63, SNRmax
Is determined to be equal to SNR2, the transmission rate is determined to be 1/2. If SNRmax is different from SNR2, the process proceeds to step S64.

In step S64, the decoding quality Q4 is set to "G
If the decoding quality Q4 is "GOOD", the process proceeds to step S65, and if the decoding quality Q4 is not "GOOD", the process proceeds to step S66.In step S65, the SNRmax is set to SNR4. If it is determined that they are equal, it is determined that the transmission rate is 1/4, and if SNRmax is different from SNR4, the process proceeds to step S66.

In step S66, the decoding quality Q8 is set to "G
It is determined whether or not the transmission quality is "ODD". When the decoding quality Q8 is "GOOD", the process proceeds to step S67. If the decoding quality Q8 is not "GOOD" in step S66, or if SNRmax is different from SNR8 in step S67, it is determined that the frame has been lost.

[0067]

As described above, the transmission rate is estimated based on both the S / N ratio of the received symbol and the decoding quality of convolutional decoding. Therefore, the reliability of the transmission rate estimation is improved as compared with the case where the transmission rate is estimated based only on the decoding quality.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a CDMA communication system of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a transmission rate estimation unit.

FIG. 3 is a flowchart illustrating an algorithm for determining a transmission rate in a transmission rate determiner.

FIG. 4 is a diagram illustrating a relationship between a transmission rate and a power train.

FIG. 5 is a block diagram illustrating another configuration of the transmission rate estimator.

FIG. 6 is a flowchart illustrating another algorithm for determining a transmission rate in a transmission rate determiner.

FIG. 7 is a block diagram showing still another configuration of the transmission rate estimator.

FIG. 8 is a diagram showing one frame of a received signal in a CDMA system.

FIG. 9 is a flowchart illustrating still another transmission rate determination algorithm in the transmission rate determiner.

FIG. 10 is a diagram illustrating a spectrum of a received signal.

FIG. 11 shows another embodiment of the receiver.

FIG. 12 is a flowchart illustrating an algorithm for determining a transmission speed in a receiver Rx2.

FIG. 13 is a diagram showing still another embodiment of the receiver.

FIG. 14 is a flowchart illustrating a determination algorithm of a transmission rate preliminary estimation in the receiver Rx3.

FIG. 15 is a flowchart illustrating an algorithm for determining a transmission speed in a receiver Rx3.

FIG. 16 is a diagram showing still another embodiment of the receiver.

FIG. 17 is a flowchart illustrating an algorithm for determining a transmission speed in a receiver Rx4.

[Explanation of symbols]

 12, 121, 122, 42 ... transmission rate estimator 16, 17, 18 ... accumulator 19, 20, 21, 22 ... power measuring instrument 23, 123, 124 ... transmission rate judging device 41: S / N ratio estimator 43: preliminary transmission rate estimator 44: decoding quality determiner

──────────────────────────────────────────────────続 き Continuation of front page (56) References JP-A-8-149567 (JP, A) JP-A-7-38620 (JP, A) JP-A-9-98150 (JP, A) JP-A-8-98 130535 (JP, A) JP-A-8-139695 (JP, A) JP-A-9-74404 (JP, A) International publication 95/1032 (WO, A1) (58) Fields investigated (Int. Cl. ⁷⁾ H04J 13/00-13/06 H04B 1/69-1/713

Claims (5)

(57) [Claims] 1. Changing the number of repetitions of the same symbol
In a transmission rate estimating apparatus for estimating the transmission rate of a code transmitted at any one of a plurality of set transmission rates, a received signal is transmitted at a predetermined band corresponding to the number of repetitions.
Compared with band limiting means for creating a plurality of band-limited signals of accumulation, the average power measuring means for obtaining respective average power of said plurality of band-limited signals, the average power of said plurality of band-limited signals, the A transmission rate estimating device comprising: a transmission rate estimating unit for estimating a transmission rate of a code inserted in a received signal. The transmission rate estimating apparatus according to claim 1, wherein the transmission rate estimating means, on the basis of the average power, the noise power density estimation unit that estimates a noise power density, the average power and the noise A transmission rate estimating unit configured to estimate a transmission rate based on the power density of the transmission rate. 3. A method in which a part of information to be transmitted is replaced by a control signal and the number of repetitions of the same symbol is changed.
In in plural set transmission rate estimation device for estimating the transmission rate of transmitted code in one of the transmission speed, and signal selecting means for selecting a valid reception signal different from the control signal, the effective Where the received signal corresponds to the number of repetitions
Comparing the band limiting means for creating a constant multiple of the band-limited signal of accumulation for each band of the average power measuring means for obtaining respective average power of said plurality of band-limited signals, the average power of said plurality of band-limited signals to the transmission rate estimating apparatus is characterized in that is composed of a transmission rate estimation means for estimating a transmission rate of code that is inserted into the received signal. 4. A variable transmission rate communication system comprising: a transmitter for transmitting information at any one of a plurality of set transmission rates; and a receiver for receiving the transmitted information. machine includes a quality measuring means for measuring a signal quality of the received signal, based on the signal quality, a transmission rate estimating means for estimating a transmission rate of code that is inserted in the reception signal, based on the received signal, said plurality Within the set transmission speed
Transmission rate preliminary estimation means for selecting transmission rate candidates from
The quality measuring means is provided by the transmission rate preliminary estimating means.
The quality of the received signal for the selected transmission rate
And the transmission rate estimating means is provided by the transmission rate preliminary estimating means.
Based on the estimation result and the measurement result of the quality measuring means,
Variable transmission rate communication characterized by estimating the transmission rate
Shin system. 5. A variable transmission rate communication system comprising: a transmitter for transmitting information at one of a plurality of set transmission rates; and a receiver for receiving the transmitted information. A signal-to-noise ratio estimating means for estimating a signal-to-noise ratio of: a decoding quality determining means for determining a decoding quality; a signal-to-noise ratio estimated by the signal-to-noise ratio estimating means; and the decoding quality determining means. A variable transmission rate communication system comprising: a transmission rate estimating unit configured to estimate a transmission rate of a code inserted in a received signal based on the determined decoding quality.