JPH06224950A - Data waveform shaping circuit - Google Patents

Abstract

PURPOSE:To obtain the data waveform shaping circuit in which stable signal waveform shaping is attained, the adjustment of a device employing the circuit is simple and the effect of a temperature is not susceptible to the circuit. CONSTITUTION:A front end 11 selects and amplifies a communication signal. A detection circuit 12 applies FM detection to an output signal of the front end 11, identifies whether or not the signal is in existence and generates a signal CD. An LPF 20 passes through a low frequency component of the output signal of the detection circuit 12. An S/H circuit 22 holds an output signal of the detection circuit 12 at the trailing of a signal SHC. A voltage comparator circuit 23 compares the output signal from the LPF 20 with an output voltage of the sample-and-hold circuit 22 and outputs a logic value corresponding to the relation of the both. A control circuit 31 generates the signal SHC based on the signal CD.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data waveform shaping circuit for shaping an output signal of a detection circuit of a receiver and reproducing data in data communication using a wireless line.

[0002]

2. Description of the Related Art In data communication using a wireless line, a data waveform shaping circuit has conventionally been constructed as described below. FIG. 6 is a diagram showing a configuration of a conventional data communication receiver 5. FIG. 7 is a diagram showing the relationship between the waveform of the signal output from the low-pass filter 53 of the conventional data communication receiver 5 and the reference voltage V _ref of the voltage comparison circuit 54.

In FIG. 6, the front end 51 selects only the radio signal used for data communication from among the radio signals captured by the antenna and converted into electrical signals.
The amplified signal is input to the detection circuit 52.

The detection circuit 52 is a circuit for performing FM detection on the output signal of the front end 51, and is shown in FIG.
It has a detection characteristic as shown in. Here, the front end 51 and the detection circuit 52 are circuits generally used in a communication system that transmits data by frequency shift keying (FSK). FIG. 3 is a diagram showing the detection characteristics of the detection circuit 52.

The low pass filter (LPF) 53 passes only the low frequency component of the output signal of the detection circuit 52 and inputs it to the voltage comparison circuit 54. Voltage comparison circuit 54
Is a low-pass filter 53 and a reference voltage V _ref created by dividing the power supply voltage by resistors R1 and R2.
The output signals of are compared and output as a data signal.

The operation of the conventional data communication receiver 5 will be described below. The front end 51 selects a signal used for data communication captured by the antenna, amplifies it, and inputs it to the detection circuit 52.

The detection circuit 52 FM-detects the output signal of the front end 51 and inputs it to the low-pass filter 53. The low-pass filter 53 passes only the low frequency component in the output signal of the detection circuit 52 and inputs it to the voltage comparison circuit 54.

Here, in the voltage comparison circuit 54, the relationship between the output signal of the low-pass filter 53 and the reference voltage V _ref is shown in FIG. 7A when the transmission frequency on the transmission side and the reception frequency on the reception side match. As shown in.

The voltage comparison circuit 54 compares the reference voltage V _ref with the output signal of the low-pass filter 53 to _obtain the reference voltage V _ref.
A part having a higher voltage than _ref has a logical value of 1, and the reference voltage V _ref
A portion having a voltage lower than that is discriminated as a logical value 0 and output.
Here, the reference voltage V _ref is equal to the output voltage V _o with respect to the center frequency f _o of the input signal of the detection circuit 52.

[0010]

Since the conventional data waveform shaping circuit is constructed as described above, it has the following problems. The characteristic of the voltage of the output signal with respect to the frequency of the input signal of the detection circuit 52 is as shown in FIG.

Before a signal is input to the front end 51 of the conventional data communication receiver 5, noise is input to the detection circuit 52. Here, this noise uniformly occurs in the frequency width of the signal selection characteristic of the front end 51. Therefore, the output voltage of the detection circuit 52 due to this noise is always an output voltage corresponding to the center frequency f _o of the signal selection characteristic substantially front end 51.

Here, when the transmission frequency on the transmission side and the reception frequency on the reception side match, the detection circuit 52 in the section where noise is input to the detection circuit 52 shown in (a) of FIG. 7A. Average value V _o of the output signal voltage and the output signal of the detection circuit 52 in the section in which the bit synchronization signal and the data are input to the detection circuit 52, as shown in (b) and (c) of FIG. The average value V _o (reference voltage V _ref ) of the voltages of the two coincides.

Therefore, the data is normally reproduced by comparing the reference voltage V _ref in the voltage comparison circuit 54 with the output signal of the low pass filter 53. In addition, the detection circuit 52
Also, the average value of the output signal of does not change suddenly.

[0014] On the other hand, the receiving frequency of the receiving and transmitting frequency of the transmitting side does not match, for example, despite the center frequency of the receiving selected frequency band is f _o,
If the transmission frequency of the transmitting side is f _2, the average value V _o (reference voltage of the output signal of the detection circuit 52 of the section noise detection circuit 52 shown in (a) shown in FIG. 7 (B) is input Voltage V _ref ) and shown in (b) and (c) of FIG.
Average value V of the voltage of the output signal of the detection circuit 52 in the section where the bit synchronization signal and the data are input to the detection circuit 52
₂ does not match.

Therefore, as shown in FIG. 7B, the reference voltage V _ref cannot be compared with the output signal of the low pass filter 53 in the voltage comparison circuit 54, and the data is not reproduced normally.

Further, the average output voltage of the detection circuit 52 suddenly changes in the section shown in (a) of FIG. 7B and the section shown after (b). As a result, even if the conventional data communication receiver 5 is configured to determine the reference voltage V _ref based on the received signal (noise) in the section shown in (a) of FIG. It is not possible to avoid problems caused by setting the voltage V _ref to a fixed value.

The data waveform shaping circuit of the present invention has been made in view of the above-mentioned problems of the prior art. In the case where the transmission frequency on the transmission side and the center frequency of the signal selection band on the reception side deviate from each other. It is possible to adaptively set the reference voltage for data waveform reproduction, and thus it is possible to stably shape and reproduce the waveform of the signal output from the detection circuit, and further, there is no need to adjust the reference voltage. An object of the present invention is to provide a data waveform shaping circuit which is not easily affected by temperature changes.

[0018]

In order to achieve the above object, the data waveform shaping circuit of the present invention uses an FS based on data.
A detection unit for detecting a reception signal which is K-modulated and preceded by a carrier of a predetermined time at the start of transmission, a filtering unit for passing a predetermined frequency component in the output signal of the detection unit, and the presence or absence of the reception signal are detected. When a valid signal is input, a voltage value holding unit that holds the output voltage value of the detection unit after a predetermined time elapses from the time when the input of the received signal is started to the end of the carrier is detected. And a voltage value comparison means for comparing the voltage value of the output signal of the filtering means with the voltage value held by the voltage value holding means and outputting a logical value corresponding to the relationship between them.

[0019]

When the signal is transmitted, the transmitting side precedes the effective data with a non-modulated carrier signal for a certain period of time. A reference voltage for data reproduction is generated by sampling / holding the output signal voltage of the detection circuit corresponding to this carrier signal at a predetermined timing. Above sample /
The hold timing is determined based on the carrier detection signal or the like asserted when the reception of the transmission signal from the transmission side is detected.

[0020]

EXAMPLES Examples of the present invention will be described below. FIG. 1 is a diagram showing a configuration of a communication system to which the data waveform shaping circuit of the present invention is applied. As shown in FIG. 1, the data waveform shaping circuit of the present invention is applied to a wireless data communication system including, for example, a pair of a data communication transmitter 2 and a data communication receiver 1.

When transmitting a signal, the data communication transmitter 2 is constructed such that an unmodulated carrier signal (unmodulated carrier) of several milliseconds, for example, 5 milliseconds is placed in front of the data to be transmitted. . Here, the data communication receiver 1 and the data communication transmitter 2 do not have to be one-to-one but may have a many-to-many configuration.

FIG. 2 is a diagram showing the structure of the data communication receiver 1 of the present invention. The data communication receiver 1 is a receiver for reproducing the original data from the reception signal that is FSK-modulated by the data signal of 4800 pbs in the transmitter on the transmission side, and is based on, for example, RCR STD-17. is there.

In FIG. 2, the front end 11 selects a signal used for data communication captured by the antenna, amplifies it, and inputs it to the detection circuit 12. Detection circuit 12
Detects the output signal of the front end 11 by FM, identifies whether or not there is an input signal for the output signal of the front end 11, asserts the carrier detect (CD) signal when there is an input signal, and If there is not, the CD signal is negated.

FIG. 3 is a diagram showing the detection characteristics of the detection circuit 12. The detection circuit 12 is a general FM detection circuit having a detection characteristic as shown in FIG. 3, and outputs a signal having a voltage value corresponding to the frequency of the signal input to the detection circuit 12.

In FIG. 3, the center frequency f_oIs front
The center frequency of the selected band of the end 11 (hereinafter, simply the reception frequency
Wave number), and the detection circuit 12 determines the frequency of the input signal.
Is f _o, The voltage V_oThe output signal of is output. same
Similarly, in the detection circuit 12, for example, when the frequency of the input signal is f₁
, The voltage V ₁Outputs the output signal of
The frequency of the input signal is f₂, The voltage V ₂Output signal of
No. is output.

The low-pass filter (LPF) 20 is a filter having a high cutoff frequency of, for example, about 0.5 to 0.7 BbT, and passes a low frequency component of the input signal equal to or lower than the high cutoff frequency. Here, BbT means a baseband normalized −3 dB frequency, and in this embodiment, since the data rate is 4800 bps, 0.5 to
0.7BbT is about 2400 Hz to 3400 Hz. By setting the high cutoff frequency of the low-pass filter 20 to this level, good data waveform reproduction becomes possible.

The sample hold (S / H) circuit 22 is
The output signal of the detection circuit 12 is held at the falling timing of the sample hold circuit control signal (SHC) of the control circuit. The output signal (S
HO) is used as a reference voltage in the voltage comparison circuit 23. Further, the sample hold circuit 22 outputs the signal SHC
While the signal is asserted, the output signal of the detection circuit 12 is directly output to the through.

The voltage comparison circuit 23 is composed of, for example, a comparator circuit including an OP amplifier, and compares the output signal of the low pass filter 20 with the output voltage value of the sample hold circuit 22 to obtain the voltage value of the output signal of the voltage comparison circuit 23. Output a logical value of 1 when is higher than the voltage value of the output signal of the sample-hold circuit 22, and outputs a logical value of 0 when it is lower.
Is output.

The control circuit 31 is composed of, for example, a CPU and controls the entire data communication receiver 1 such as setting an oscillation frequency in a local oscillation circuit (not shown) of the data communication receiver 1. , A signal SHC that is asserted almost at the same time as the assertion of the signal CD output from the detection circuit 12 and negates after a predetermined time elapses, and holds (holds) the voltage value of the output signal of the detection circuit 12 with respect to the sample hold circuit 22. ) Is specified.

When the control circuit 31 is used only for processing the signal SHC, it can be realized by a combination of very simple logic elements. The signal SHC is not limited to the signal CD, and the control circuit 31 and other parts may be configured to be generated based on another signal, for example, a squelch signal.

FIG. 4 is a diagram showing a signal waveform of each part of the data communication receiver 1. In FIG. 4, the waveform shown in (A) is the waveform of a carrier detect (CD) signal. The signal CD becomes a logical value 1 (asserted) when input regardless of whether the signal from the data communication transmitter 2 is modulated or unmodulated, and the signal from the data communication transmitter 2 becomes This value is held until there is no input.

The waveform shown in (B) is the waveform of the sample and hold circuit control signal (SHC) signal. Signal SHC
Is generated by the control circuit 31, becomes a logical value 1 (asserted) at the same time as the signal CD is asserted, holds this value for the time indicated by (T) in the figure, and is then negated.

This time T is the transmission time of an unmodulated carrier which is prepended to the data at the time of transmission by the data communication transmitter 2,
That is, in this embodiment, it can be set to about 5 msec.

At the fall of the signal SHC, the sample hold circuit 22 holds the voltage value of the output signal of the detection circuit 12. The waveform shown in (C) is the waveform of the output signal (DETO1) of the low-pass filter 20 when the transmission frequency and the reception frequency on the transmission side match. The waveform shown in (D) is the waveform of the output signal (SHO1) of the sample hold circuit 22 when the transmission frequency and the reception frequency on the transmission side match.

The waveform shown in (E) is the waveform of the output signal (DETO2) of the detection circuit 12 when the transmission frequency on the transmission side does not match the reception frequency. The waveform shown in (F) is
It is a waveform of the output signal (SHO2) of the sample hold circuit 22 when the transmission frequency on the transmission side does not match the reception frequency. Here, regarding the signal DETO2 and the signal SHO2, the case where the transmission frequency on the transmission side is the frequency f ₂ is shown.

The operation of the data communication receiver 1 will be described below. The front end 11 selects a signal used for data communication captured by the antenna, amplifies it, and inputs it to the detection circuit 12. The detection circuit 12 has a front end 11
Of the output signal of the front end 11 is discriminated whether or not there is an input signal from the transmitter 2 for data communication, and if there is an input signal, a carrier detect (CD) signal is asserted. If there is no input signal, negate the CD signal.

The signal CD is input to the control circuit 31. The output of the detection circuit 12 is input to the low pass filter 20 and the sample hold circuit 22. The low-pass filter 20 takes out low-frequency components below the above high-frequency cutoff frequency and inputs them to the voltage comparison circuit 23.

The control circuit 31 asserts the signal SHC as well as the signal CD. This signal SHC is negated after a predetermined time (T) has elapsed. Here, the sampling time (T) of this signal SHC is (C) of FIG.
Unmodulated carrier reception time (5 m) shown in (b) in (E)
It is set to about 2 seconds) and a time for which the output value of the detection circuit 12 is sufficiently stable.

When the transmission frequency of the transmission side and the reception frequency of the data communication receiver 1 match, the output voltage of the sample hold circuit 22 does not change as shown in FIG. 4 (D). Therefore, by holding the output signal of the detection circuit 12 at the timing shown in the figure and comparing it with the voltage comparison circuit 23, it is possible to properly shape the data waveform and reproduce the data.

On the other hand, when the transmission frequency of the transmission side and the reception frequency of the data communication receiver 1 do not match, FIG.
Like the waveform of the output signal of the sample hold circuit 22 (the output signal of the detection circuit 12) shown in (F), the boundary between the waveforms of the section (a) and the section (b), that is, the unmodulated carrier is input. Before and after that, the voltage of the output signal of the detection circuit 12 suddenly changes.

In such a case, the reference voltage in the voltage comparison circuit 23 is fixed as shown in the conventional example. Alternatively, even if the average voltage of the signal DETO2 in the section (a) is used as the reference voltage, normal data waveform shaping and data reproduction cannot be performed.

However, after a lapse of a predetermined time (T) from the assertion of the signal CD, the sample hold circuit 2
The output waveform of 2 (the output signal of the detection circuit 12) is shown in FIG.
The voltage of the signal shown in the section (b) of (E) (voltage proportional to the center frequency on the transmission side) (V ₂ ) is obtained, and this voltage V
_By setting ₂ as the reference voltage of the voltage comparison circuit 23, it is possible to properly shape the data waveform and reproduce the data.

FIG. 5 is a diagram showing a waveform when the signal SHO and the signal DETO are overlapped. In FIG. 5, the waveform shown in (A) is the transmission frequency of the transmission side and the receiver 1 for data communication.
Signal SHO and signal D when the reception frequencies of the
The relationship of ETO is shown.

The waveform shown in (B) shows the relationship between the signal SHO and the signal DETO when the transmission frequency on the transmission side and the reception frequency of the data communication receiver 1 do not match.

As described above, when the transmission frequency of the transmission side and the reception frequency of the data communication receiver 1 match, as well as when they do not match, the low-pass at the timing shown in FIG. By holding the output signal of the filter 20 and using it as the reference voltage in the voltage comparison circuit 23, the data waveform can be shaped and the data can be reproduced normally.

Each part of the data communication receiver 1 described above can be replaced with another circuit having an equivalent function. The relationship between the assertion / negation of each signal and the logical value does not have to be the same as that of the present embodiment, and may be negative logic, or may be a configuration in which positive logic and negative logic are mixed.

Further, the data waveform shaping circuit of the present invention is not only applied to wireless communication, but can be widely applied to a communication device for transmitting and receiving data using the FSK modulation method. The data waveform shaping circuit of the present invention may have various configurations other than those described above, for example, as shown in the above modified examples. The embodiments described above are merely examples.

[0048]

As described above, according to the data waveform shaping circuit of the present invention, the reference voltage for data waveform reproduction is adaptively adjusted when the transmission frequency on the transmission side and the center frequency of the signal selection band on the reception side deviate from each other. Therefore, it is possible to stably shape and reproduce the waveform of the signal output from the detection circuit, and it is not necessary to adjust the reference voltage, and the data waveform is not easily affected by temperature changes. A shaping circuit can be provided.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a communication system to which a data waveform shaping circuit of the present invention is applied.

FIG. 2 is a diagram showing a configuration of a receiver for data communication of the present invention.

FIG. 3 is a diagram showing a detection characteristic of a detection circuit.

FIG. 4 is a diagram showing signal waveforms of respective portions of the data communication receiver.

FIG. 5 is a diagram showing waveforms when a signal SHO and a signal DETO are superposed.

FIG. 6 is a diagram showing a configuration of a conventional data communication receiver.

FIG. 7 is a diagram showing a relationship between a waveform of a signal output from a low-pass filter of a conventional data communication receiver and a reference voltage V _ref of a voltage comparison circuit 54.

[Explanation of symbols]

 1 ... Receiver for data communication 11 ... Front end 12 ... Detection circuit 20 ... Low pass filter 22 ... Sample hold circuit 23 ... Voltage comparison circuit 31 ... Control circuit 2 ...・ Transmitter for data communication

Claims (1)

[Claims] 1. A detection means for detecting a reception signal, which is FSK-modulated by data and is preceded by a carrier of a predetermined time at the start of transmission, and a time point at which the presence or absence of the reception signal is detected and the reception signal is started. Voltage value holding means for holding the output voltage value of the detection means after a lapse of a predetermined time from before to the end of the carrier, and the voltage value of the output signal of the detection means only when a valid signal is input. A data waveform shaping circuit having voltage value comparison means for comparing the voltage value held by the voltage value holding means and outputting a logical value corresponding to the relationship between the two.