JPH07212429A - Data receiver - Google Patents

Abstract

PURPOSE:To correct an oscillation frequency to a carrier wave frequency even when the oscillation frequency of an oscillator used for synchronization detection is provided with a large frequency deviation to the carrier wave frequency. CONSTITUTION:Signals outputted from the oscillator are used and phase modulated reception signals are synchronization-detected in a detection means 3. A base band signal correlation detection means 6 for investigating the correlation of base band signals and plural reference signals prepared beforehand and detecting a frequency deviation level between the oscillation frequency and the carrier wave frequency is provided and the oscillation frequency of the oscillator 2 is changed based on the detected result of the base band signal correlation detection means. When the frequency deviation between the oscillation frequency of the oscillator 2 and the carrier wave frequency is at a level which can not be corrected just by the control utilizing the identified result of an identification means 5, the base band signal correlation detection means detects it and the oscillator 2 brings the oscillation frequency back to the frequency deviation level which can be corrected just by the control of the identification means 5 based on the detected result.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data receiving apparatus used for a digital automobile telephone or the like, and more particularly to a data receiving apparatus which can be accurately synchronized with a carrier frequency.

[0002]

2. Description of the Related Art In phase-modulation communication in which information is transmitted by changing the phase of a carrier wave, a receiving side converts a baseband signal by synchronous detection by multiplying a received signal by a signal output from an oscillator having the same frequency as the carrier wave. Demodulating. If there is a deviation between the oscillation frequency of the oscillator and the carrier frequency, an error will occur in decoding. Therefore, in the phase modulation type data receiving device, there is a means for making the oscillation frequency of the oscillator follow the carrier frequency. It is provided.

As shown in FIG. 6, a conventional data receiving apparatus of this type has an input terminal 1 for inputting a received signal, a detector 3 for obtaining a baseband signal from the input received signal, and a carrier frequency of the received signal. And a clock regenerator 4 for producing a regenerated clock signal indicating the identification timing of the baseband signal based on the zero cross signal obtained from the baseband signal output from the detector 3.
And a discriminator 5 for discriminating the data transmitted by the baseband signal using the reproduced clock signal generated by the clock regenerator 4, and an output end 6 for outputting the received data.

In this data receiving device, when a signal is received, the detector 3 synchronously detects the received signal using the signal having the carrier frequency component of the received signal reproduced by the oscillator 2 and outputs the baseband signal. . If the data to be transmitted is random data, the polarity of the baseband signal changes at an average time 1/2 hour after the identification time of the data. The clock regenerator 4 detects a zero-cross signal indicating this change in polarity, and uses the zero-cross signal as a reference so that the time difference between the zero-cross signal and the data identification timing is ½ of the data identification interval. Generate data identification timing. The discriminator 5 discriminates whether the baseband signal is positive or negative at the discrimination timing created by the clock regenerator 4, and outputs the received data from the output end 7 based on the discrimination result. Further, the error signal at the time of the discrimination by the discriminator 5 is fed back to the oscillator 2 and is controlled so that the frequency of the oscillator 2 follows the carrier frequency.

In QPSK which is a four-value phase modulation system,
As shown in FIG. 2, in the phase diagram in which the in-phase component is represented by the I axis and the quadrature component is represented by the Q axis, signal points of symbols are set at positions rotated by π / 4 from the I axis and the Q axis, respectively. The discriminator 5 of the data receiving device determines whether the in-phase component and the quadrature component of the received baseband signal are positive or negative, and when both the in-phase component and the quadrature component are positive (1, 1), the in-phase component is positive, When the quadrature component is negative (1, -1), the in-phase component is negative, when the quadrature component is positive (-1, 1), when both the in-phase component and the quadrature component are negative (-1, -1) ), The signal point of the symbol is identified.

The information to be transmitted is represented by the phase difference between the symbols to be transmitted. For example, the transmitting side sets the phase change amount to π / 2 when it represents "00" and the phase change amount when it represents "01". The change amount is π, the phase change amount is 0 when the value is “10”, and the phase change amount is − when the value is “11”.
Set to π / 2. On the other hand, as shown in FIG. 2, on the receiving side, when the symbol (-1, 1) is identified after the symbol (1, 1), that is, from the initial phase of π / 4 to + π / 2.
If it is identified that there is a phase change of the symbol, "00" is decoded, and the symbol (-1, 1) is followed by the symbol (-
, −1), that is, when the phase change amount of π is identified, “01” is decoded. Similarly, when the phase change amount of 0 is identified, “10”, −π / 2. When the phase change amount of is identified, "11" is decoded.

Such decoding can be performed without error by making the oscillation frequency of the oscillator 2 in the data receiving device follow the carrier frequency correctly. Therefore, the discriminator 5 is the detector 3 in the phase diagram.
An error signal corresponding to the phase difference between the signal point representing the output of the signal and the signal point of the identified symbol is output to the oscillator 2.
The oscillator 2 controls the oscillation frequency so as to eliminate this error. By doing so, the oscillation frequency of the oscillator 5 is kept equal to the carrier frequency when the frequency difference is not large.

[0008]

However, in the conventional data receiving apparatus, when the frequency deviation Δf between the oscillation frequency of the oscillator and the carrier frequency is larger than ± 1/8 of the symbol transmission rate of the transmission data. However, there is a problem in that the oscillation frequency of the oscillator cannot follow the carrier frequency and a large transmission error occurs.

The frequency deviation Δf between the oscillation frequency of this oscillator and the carrier frequency produces a phase error θe of the baseband signal corresponding to θe = 2πΔf / fr (where fr is the symbol transmission rate). Is | Δf | ≧ fr / 8
In this case, the phase error θe becomes π / 4 or more, and the signal point of the baseband signal output from the detector 3 deviates from the quadrant where the original signal point exists on the phase diagram. Therefore, the discriminator 5 incorrectly identifies the signal point, and the discriminator 5 sends an inaccurate error signal to the oscillator 2, resulting in a large transmission error.

The present invention solves these conventional problems, and the oscillation frequency of the oscillator used for synchronous detection is higher than ± 1/8 of the symbol transmission rate of transmission data with respect to the carrier frequency. It is an object of the present invention to provide a data receiving device that can correct the oscillation frequency of an oscillator to a carrier frequency even if there is a deviation.

[0011]

Therefore, in the present invention, an oscillator for reproducing a carrier frequency component of a received signal, and a detection means for synchronously detecting a phase-modulated received signal using a signal output from the oscillator are provided. A data receiving device that includes an identifying unit that identifies the transmission data using the baseband signal output from the detecting unit, and that controls the oscillation frequency of the oscillator using the identification result of the identifying unit. Baseband signal correlation detection means for detecting the frequency deviation level between the oscillation frequency and the carrier frequency by checking the correlation with a plurality of prepared reference signals is provided, and the oscillator is based on the detection result of the baseband signal correlation detection means. It is configured to change the oscillation frequency of.

Further, in this data receiving device, QPSK
It is configured to receive the modulated signal.

Further, this data receiving device is configured to receive a π / 4 shift QPSK modulated signal.

Further, as a reference signal, a baseband signal obtained by phase-modulating a known data sequence on the transmitting side and the receiving side, and 1 / n (n is a positive number) of the symbol transmission rate of the transmission data of this baseband signal. -A baseband signal obtained by modulating with a frequency of a negative integer) is used.

Further, the phase modulation of this data string is performed by QPSK.
Alternatively, it is performed by π / 4 shift QPSK.

Further, a synchronization word of a TDMA frame is used as this data string.

[0017]

Therefore, when the frequency deviation between the oscillation frequency of the oscillator and the carrier frequency is at a level that cannot be corrected only by controlling the oscillation frequency using the identification result of the identification means, the baseband signal correlation detection means Upon detecting it, the oscillator pulls the oscillation frequency back to a frequency deviation level that can be corrected only by controlling the identification means, based on the detection result.

The baseband signal correlation detecting means is a TDM
A baseband signal obtained by phase-modulating a known data sequence on the transmitting / receiving side, such as a synchronization word of an A frame, and a frequency of 1 / n (n is a positive or negative integer) of the symbol transmission rate of transmission data. Prepared as a reference signal, and by checking the correlation between the prepared reference signal and the baseband signal output from the detection means when receiving the known data string, the level of the frequency deviation To detect.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A data receiving apparatus according to an embodiment of the present invention is
As shown in FIG. 1, a baseband signal correlator 6 for checking the correlation between a baseband signal obtained from a received signal of a known data sequence and some reference signals is provided. The baseband signal correlator 6 determines the frequency deviation Δf between the oscillation frequency of the oscillator and the carrier frequency from the highly correlated reference signal.
Is 1/8 or more of the symbol transmission rate fr of the transmission data, is -1/8 or less, or is in between, and sends the detection result to the oscillator 2. The oscillator 2 controls the oscillation frequency using the error signal sent from the discriminator 5 and the detection result. Other configurations are the same as those of the conventional device (FIG. 6).

The operation of this data receiving apparatus will be described. When the QPSK-modulated reception signal is input from the input terminal 1, the detector 3 synchronously detects the reception signal using the signal having the carrier frequency component of the reception signal regenerated by the oscillator 2, and outputs the baseband signal. . Clock regenerator 4
Generates a discrimination timing with reference to the zero-cross signal of the baseband signal, and the discriminator 5 discriminates the positive / negative of the baseband signal at this discrimination timing to discriminate the signal point of the symbol. Then, an error signal corresponding to the phase difference between the signal point of the identified symbol and the signal point of the baseband output from the detector 3 is fed back to the oscillator 2, and the oscillator 2 sets the error signal to zero. Control the oscillation frequency. This series of operations is the same as the operation in the conventional device.

As a result of this control, when the absolute value of the frequency deviation Δf between the oscillation frequency of the oscillator 2 and the carrier frequency is smaller than 1/8 of the symbol transmission rate fr of the transmission data, the oscillation frequency of the oscillator 2 Correctly follows the carrier frequency. Now, the transmitting side sets the phase change amount to π / 2 to represent data “00”, the phase change amount to π to represent “01”, and the phase change amount to 0 to represent “10”.
In addition, the phase change amount is −π / to represent “11”.
If it is set to 2, when the oscillation frequency of the oscillator 2 is correctly controlled, as shown in FIG. 2 (in FIG. 2, the initial phase is π / 4), the discriminator 5
Identifies the phase change amount as π / 2 when the transmitted data is “00”, the phase change amount as π when the transmitted data is “01”, and the phase change amount as 0 when the transmitted data is “10”. , And when "11", the phase change amount is identified as -π / 2,
Correct transmission data is decoded based on the identification.

However, in the case of | Δf | ≧ fr / 8, correct data cannot be decoded only by sending the error signal from the discriminator 5 to the oscillator 5. This means that when the oscillation frequency of the oscillator 2 is higher than the carrier frequency of the received signal by fr / 8 or more, a phase error θe exceeding π / 4 occurs between the signal point of the baseband and the signal point of the original symbol. However, for that reason, the discriminator 5 discriminates the signal point of the baseband as a signal point of the symbol shifted by −π / 2. As a result, as shown in FIG. 3, the discriminator 4 determines the phase change amount by π when the transmission data is “01”.
/ 2, the phase change amount is identified as π when the transmission data is "11", the phase change amount is identified as 0 when the transmission data is "00", and the transmission data is "10". In this case, the phase change amount is identified as −π / 2. At this time, the discriminator 5 determines that the detector 3 has a symbol transmission rate of 1/1 / th
Since I do not know that the carrier frequency is higher than 8 is detected, according to the normal relationship between the amount of phase change and the data,
The transmission data of "01" is set to "00", the transmission data of "11" is set to "01", and the transmission data of "00" is set to "10".
In addition, the transmission data of "10" is decoded into "11".

On the contrary, when the oscillation frequency of the oscillator 2 is lower than the carrier frequency of the received signal by fr / 8 or more,
The discriminator 5 discriminates the signal point of the baseband as the signal point of the symbol shifted by π / 2. As a result, as shown in FIG. 4, the discriminator 4 discriminates the phase change amount as π / 2 when the transmission data is “10”, and the transmission data is “0”.
The phase change amount is identified as π when the transmission data is “11”, the phase change amount is identified as 0 when the transmission data is “11”, and the phase change amount is −π / when the transmission data is “01”. According to the normal relationship between the amount of phase change and the data, the transmission data of “10” is set to “00”, the transmission data of “00” is set to “01”, and the transmission data of “11” is set. "1
The transmission data of "0" and the transmission data of "01" are decoded into "11".

In order to eliminate such decoding error, three types of reference signals obtained by subjecting a known data sequence to different modulation are prepared in the baseband signal correlator 6, and these reference signals and their data are transmitted on the transmitting side. The baseband signal correlator 6 calculates a correlation value with the baseband signal output from the detector 3 when the sequence is transmitted, and detects which reference signal has the highest correlation.

As the known data series, as shown in FIG. 5, a sync word included in each frame of the data format TDMA communication can be used. The baseband signal correlator 6 uses a baseband signal (referred to as a “first reference signal”) obtained by QPSK-modulating this synchronization word as a reference signal, and a symbol transmission rate fr of the transmission data for the first reference signal. Of the baseband signal (referred to as "second reference signal") obtained by modulating at a frequency of 1/4 of the above, and the first reference signal at a frequency of -1/4 of the symbol transmission rate fr of the transmission data. Three types of signals including the obtained baseband signal (referred to as “third reference signal”) are prepared.

The baseband signal correlator 6 calculates the respective correlation values of the baseband signal output from the detector 3 and the three types of reference signals when the synchronization word is received,
The reference signal with the strongest correlation is detected.

When the correlation with the first reference signal is strongest,
Since it indicates that the frequency deviation Δf between the oscillation frequency of the oscillator 2 and the carrier frequency is ± fr / 8 or less,
No signal is sent from the baseband signal correlator 6 to the oscillator 2. In this case, the oscillation frequency of the oscillator 2 can follow the carrier frequency only by controlling the error signal output from the discriminator 5.

When the correlation with the second reference signal is strongest,
Since the oscillation frequency of the oscillator 2 is separated from the carrier frequency by fr / 8 or more, the baseband correlator 6 changes the oscillation frequency of the oscillator 2 by -fr / 4 from the current frequency. Give instructions to do. As a result, the oscillation frequency of the oscillator 2 has a frequency deviation Δf from the carrier frequency of ± fr / 8 or less, and the oscillation frequency can be made to follow the carrier frequency only by controlling the error signal output from the discriminator 5. become.

When the correlation with the third reference signal is the strongest, the oscillation frequency of the oscillator 2 is -fr from the carrier frequency.
Since it indicates that they are apart from each other by / 8 or more, the baseband correlator 6 gives an instruction to the oscillator 2 to change the oscillation frequency by fr / 4 from the current frequency. As a result, the oscillation frequency of the oscillator 2 has a frequency deviation Δf from the carrier frequency of ± fr / 8 or less, and the discriminator 5
The oscillation frequency can be made to follow the carrier wave frequency only by controlling the error signal output from.

As described above, in the data receiving apparatus of the embodiment, the correlation between the baseband signal output from the detector 3 and the reference signal is checked to detect the level of Δf, and Δ
When the absolute value of f is fr / 8 or more, Δf is fr / 8
By controlling the oscillation frequency of the oscillator 2 as follows, the oscillation frequency of the oscillator can be quickly and reliably synchronized with the carrier frequency.

In the embodiment, the case of receiving the data of QPSK modulation was explained exclusively, but the data receiving apparatus of the present invention is π / 4 shift QPSK modulation, that is, on the I and Q axes at a certain time. The operation of transmitting any one of the four symbols and then transmitting any one of the four symbols on the axis rotated by π / 4 from the I and Q axes at the next time is repeated. The same function can be applied to the case of receiving the data of the modulation method for transmitting the information according to the phase difference of the. Further, even when handling QPSK-modulated data, a baseband signal obtained by subjecting a data sequence to π / 4 shift QPSK modulation can be used as the reference signal prepared in the baseband signal correlator 6, and vice versa. In addition, even when the data of π / 4 shift QPSK modulation is handled, the baseband signal obtained by QPSK modulating the data sequence can be used as the reference signal.

Further, by further developing the idea of the embodiment, it is possible to appropriately correct the oscillation frequency of the oscillator even when the frequency deviation Δf between the oscillation frequency of the oscillator and the carrier frequency is larger. become.

[0033]

As is apparent from the above description of the embodiments, the data receiving apparatus of the present invention can quickly and surely synchronize the oscillation frequency of the oscillator used for synchronous detection with the carrier frequency, and QPSK. Or π / 4 shift QPS
The K data can be correctly decoded.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a data receiving apparatus of the present invention,

FIG. 2 is a correspondence diagram between transmission data and baseband signals (Δ
f = 0),

FIG. 3 is a correspondence diagram between transmission data and baseband signals (Δ
f ≧ π / 4),

FIG. 4 is a correspondence diagram (Δ) between transmission data and baseband signals.
f ≦ −π / 4),

FIG. 5 is a block diagram showing a data format of a TDMA frame,

FIG. 6 is a block diagram showing a configuration of a conventional data receiving device.

[Explanation of symbols]

 1 Input Terminal 2 Oscillator 3 Detector 4 Clock Regenerator 5 Discriminator 6 Baseband Correlator 7 Output Terminal

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁶ Identification number Internal reference number FI Technical indication H04L 27/22 9297-5K H04L 27/22 B 9297-5K C (72) Inventor Koichi Homma Kanagawa Matsushita Communication Industry Co., Ltd. 4-3-1, Tsunashima-higashi, Kohoku-ku, Yokohama-shi

Claims (6)

[Claims] 1. An oscillator for reproducing a carrier frequency component of a received signal, a detection means for synchronously detecting a received signal phase-modulated using the signal output from the oscillator, and a base output from the detection means. A data receiving device, comprising: an identification unit for identifying transmission data using a band signal, and controlling the oscillation frequency of the oscillator by using the identification result of the identification unit, wherein the baseband signal and a plurality of references prepared in advance Providing baseband signal correlation detection means for detecting the frequency deviation level between the oscillation frequency and the carrier frequency by checking the correlation with the signal, and the oscillation frequency of the oscillator based on the detection result of the baseband signal correlation detection means. A data receiving device characterized by changing the. 2. The data receiving apparatus according to claim 1, wherein the phase modulation is QPSK modulation. 3. The phase modulation is π / 4 shift QPSK.
The data receiving apparatus according to claim 1, wherein the data receiving apparatus is modulation. 4. A baseband signal obtained by phase-modulating a known data sequence on the transmitting side and the receiving side as the reference signal, and 1 / n (n is the symbol transmission rate of the symbol transmission rate of the transmission data of the baseband signal). 4. A data receiving apparatus according to claim 1, wherein a baseband signal obtained by modulating at frequencies of positive and negative integers) is used. 5. The data receiving apparatus according to claim 4, wherein the phase modulation of the data string is performed by QPSK or π / 4 shift QPSK. 6. The data receiving apparatus according to claim 4, wherein a synchronization word of a TDMA frame is used as the data string.