JP2000244355A - Selective radio call receiver, and local frequency generating method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a selective radio call receiver capable of preventing deterioration of receiving sensitivity even when there is deviation in local frequencies caused by a temperature, etc. SOLUTION: The receiver is provided with an antenna for receiving a signal transmitted from a base station, a radio part 2 for amplifying and demodulating a received signal, a local part 3 for generating a local frequency for converting the frequency of the received signal, a control part 4 controlling the part 3 by decoding a signal demodulated by the part 2. The part 4 counts the number of the erroneous bits of the received signal while varying the local frequency and controls the part 3 to generate a local frequency signal of a frequency minimizing the number of the erroneous bits. Thus, it is possible to prevent deterioration of receiving sensitivity even when there is deviation of local frequencies caused by a temperature, etc.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio selective calling receiver and, more particularly, to a radio selective calling receiver for preventing deterioration of reception sensitivity and a local frequency generating method.

[0002]

2. Description of the Related Art A conventional radio selective call receiver is shown in FIG.
, An antenna 51, a radio unit 52, a local unit 53, a control unit 54, an EEPROM 55,
It has an AM 56, a ROM 57, and a display unit 58.

[0005] An antenna 51 receives a signal transmitted from a base station (not shown). Radio section 52 amplifies and demodulates the received signal. The local unit 53 generates a local frequency for converting a received signal into an intermediate frequency,
Send to The control unit 54 decodes the signal demodulated by the wireless unit 52. The calling number of the terminal, the data of the receiving frequency, and the like are written in the EEPROM 55. If the decoded signal is its own calling, the control unit 54 performs a process programmed in the ROM 57 and displays a message on the display unit 58. I do.

[0004]

However, there arises a problem that the receiving sensitivity is degraded due to a deviation of the local frequency generated by the local unit with respect to a temperature change.

[0005] The temperature deviation of the local frequency is dominated by the temperature deviation of the oscillation frequency of the crystal used for the reference clock of the phase locked loop provided in the local unit. However, there is a problem that the unit price is not 0 and the unit price of the component increases as the temperature deviation decreases.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has a radio selective calling receiver and a local frequency generation method capable of preventing reception sensitivity from being deteriorated even when a local frequency shifts due to temperature or the like. The purpose is to provide.

[0007]

SUMMARY OF THE INVENTION In order to achieve the above object, a radio selective call receiver according to the present invention is a radio selective call receiver for selectively receiving a radio signal, wherein the frequency of the received signal is set to a predetermined value. Local frequency generating means for generating a local frequency signal for converting to frequency, a received word number detecting means for detecting the number of received words of the received signal, and an error bit number detecting means for detecting an error bit number of the received signal, Error rate calculation means for calculating the ratio of the number of error bits to the number of received words, and control means for controlling the local frequency generation means, wherein the control means comprises: Is larger than the ratio of the number of error bits to the number of words received by the previous received signal, the frequency of the current received signal is From the frequency of the previous local frequency signal used for conversion, in the same direction as the conversion direction to the frequency of the local frequency signal two times before used for converting the frequency of the previous received signal to the predetermined frequency Generates a local frequency signal obtained by converting the frequency of the previous local frequency, and the ratio of the number of error bits to the number of words received by the current reception signal is smaller than the ratio of the number of error bits to the number of words received by the previous reception signal. Control the local frequency generating means to generate a local frequency signal obtained by converting the frequency of the previous local frequency in the same direction as the conversion direction from the frequency of the local frequency signal two times before to the frequency of the previous local frequency signal. It is characterized by doing.

The control means has frequency range detection means for detecting whether or not the local frequency used for conversion of the current reception signal exceeds the upper limit frequency and the lower limit frequency. When it is detected that the local frequency used for the conversion of the received signal has reached the upper limit frequency, the local frequency generating means is controlled to generate a local frequency signal having a frequency lower than the upper limit frequency, and the frequency range is detected. Controlling the local frequency generating means to generate a local frequency signal having a frequency higher than the lower limit frequency when detecting that the local frequency used for the conversion of the current reception signal has reached the lower limit frequency by the means; It is characterized by.

The control means has a detection means for detecting whether or not the received signal is a signal received for the first time after the power of the radio selective calling receiver is turned on, wherein the ratio of the number of error bits to the received signal is 0. If the reception is not the first reception after the power is turned on, the local frequency generation means is controlled to generate a local frequency whose frequency is raised by a predetermined amount from a preset reference frequency.

The above-mentioned radio selective calling receiver has a constant voltage output means having an output voltage having a linearity with respect to a temperature.
A demodulating means for demodulating the received signal; wherein the control means generates the local frequency by means of a difference between an output voltage of the constant voltage output means and a reference voltage outputted by the constant voltage output means at a predetermined reference temperature. The frequency conversion direction of the local frequency signal is controlled.

The above-mentioned local frequency generating means includes voltage-controlled oscillating means for oscillating and outputting a local frequency signal for converting the frequency of a received signal to a predetermined frequency, and a reference clock generating means for generating a reference clock signal of a predetermined frequency. Means for dividing the local frequency signal output from the voltage controlled oscillation means by a frequency division number set by the control means.
Frequency dividing means, a second frequency dividing means for dividing the reference clock signal generated by the reference clock generating means by a predetermined frequency division number, and a local frequency signal divided by the first frequency dividing means. Phase comparison means for comparing the phase with the reference clock signal divided by the second frequency division means and outputting a phase difference signal corresponding to the phase difference, and corresponding to the phase difference by the phase difference signal from the phase comparison means And a voltage supply means for outputting the set voltage value to the voltage control oscillation means.

A local frequency generating method according to the present invention is a local frequency generating method for a radio selective calling receiver for selectively receiving a radio signal, the method comprising the steps of detecting the number of received words of a received signal; An error bit number detecting step of detecting the number of error bits of the received signal, an error rate calculating step of calculating a ratio of the number of error bits to the number of received words, and a ratio of the number of error bits to the number of received words of the current received signal. If the ratio of the number of error bits to the number of words received by the received signal is larger than the frequency of the previous local frequency signal used to convert the frequency of the current received signal to a predetermined frequency, The same direction as the frequency of the local frequency signal that was used to convert the frequency of the signal to the specified frequency two times before A first local frequency generating step of generating a local frequency signal obtained by converting the frequency of the previous local frequency, and the ratio of the number of error bits to the number of words received by the current received signal is different from the error of the number of received words by the previous received signal. If the ratio is smaller than the bit number ratio, a local frequency signal is generated by converting the frequency of the previous local frequency in the same direction as the conversion direction from the frequency of the local frequency signal two times before to the frequency of the previous local frequency signal. And a second local frequency generation step.

A frequency range detecting step for detecting whether or not the local frequency used in the conversion of the current reception signal exceeds the upper limit frequency and the lower limit frequency, and a conversion of the current reception signal by the frequency range detection step. When detecting that the used local frequency has reached the upper limit frequency, a third local frequency generation step of generating a local frequency signal having a frequency lower than the upper limit frequency, and a frequency range detection step of the present reception signal. And a fourth local frequency generation step of generating a local frequency signal having a frequency higher than the lower limit frequency when detecting that the local frequency used for the conversion has reached the lower limit frequency.

The above-described local frequency generation method includes a detecting step of detecting whether the received signal is a signal received for the first time after the power of the radio selective calling receiver is turned on, and a step of determining whether the ratio of the number of error bits to the received signal is zero. And a fifth local frequency generation step of generating a local frequency whose frequency is raised by a predetermined amount from a preset reference frequency when the first reception is performed after the power is turned on. .

[0015]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a preferred embodiment of a radio selective calling receiver and a local frequency generating method according to the present invention; 1 to 7 show an embodiment of a radio selective call receiver and a local frequency generation method according to the present invention.

FIG. 1 shows a first embodiment according to the present invention. As shown in FIG. 1, the present embodiment includes an antenna 1, a radio unit 2, a local unit 3, and a control unit 4.
, An EEPROM 5, a RAM 6, a ROM 7, and a display unit 8.

The antenna 1 receives a signal transmitted from a base station (not shown). Radio section 2 amplifies and demodulates the signal received by antenna 1. The local unit 3 generates a local frequency for converting a received signal into an intermediate frequency. The control unit 4 decodes the signal demodulated by the wireless unit 2. The calling number of the terminal, the data of the receiving frequency, and the like are written in the EEPROM 5, and the control unit 4 reads the ROM if the decoded signal is its own calling.
7 and displays a message on the display unit 8. The RAM 6 is used for each process of the control unit 4 and can be used in various ways.

Various signals are currently proposed for a signal transmitted from a base station (not shown), and any of the protocols is converted into error bit correctable data and transmitted. For example, POCSAG (Post Office Code
In Standardization Advisory Group), 11 bits of check bits are added to 21 bits of information, and the information is transmitted as 32 bits per word.

The control unit 4 decodes the demodulated signal and extracts information bits conforming to the protocol. At this time, the control unit 4 detects the number of error bits by using check bits. For example, PO
With CSAG, errors of up to 3 bits can be detected.

FIG. 2 shows a detailed configuration of the local unit 3 for generating a local frequency signal. The local part is a reference voltage oscillator [VCO (Voltage Controlled
Oscillator)], a phase synchronizer 10 and a reference clock generator 16. The reference voltage oscillator 9 compensates for a phase difference component between the reference clock from the reference clock generator 16. Oscillates and outputs a local frequency signal.

The phase synchronizer 10 includes a low-pass filter 11
, A charge pump 12, a frequency divider 13, a phase comparator 14, and a frequency divider 15.

When the phase synchronizer 10 is in the initial operating state, the reference clock signal oscillated from the reference clock generator 16 is divided by the frequency divider 15 and then input to the phase comparator 14. . The local frequency signal oscillated and output from the VCO 9 is also input to the phase comparator 14 after being divided by the frequency divider 13. The phase comparator 14 outputs a phase difference signal corresponding to the phase difference between the voltages of the frequency dividers 13 and 15. The phase difference signal output from the phase comparator 14 passes through the charge pump 12 and the low-pass
The VCO 9 oscillates and outputs a local frequency signal in which the phase difference component is compensated. As a result, a stable output frequency synchronized with the reference clock signal can be obtained.

For example, if the line frequency of 930 MHz is 2
When converting to an intermediate frequency of 9.25 MHz, the frequency required for the VCO is 900.75 MHz. If the frequency for performing phase comparison in the phase synchronization unit 10 using 14.4 MHz as the reference clock and 1 KHz, the frequency division number Is 14400 for the reference clock and 900750 for the VCO.

In the above example, if only the frequency division number of the VCO is increased by 1, the local frequency becomes 900.751 MHz, and if it is decreased by 1, the local frequency becomes 900.749 MHz. That is, the frequency for performing the phase comparison represents a frequency that can be set in the VCO.

In general, an oscillation circuit using a crystal having high frequency stability is used as a reference clock. However, since the oscillation frequency of the crystal changes depending on the temperature, it is necessary to use a crystal having a small temperature deviation in order to keep the local frequency stable with respect to the temperature change.

However, the temperature deviation is not 0, and in addition, the yield is reduced due to the stricter specifications, which causes a problem that the unit price increases.

As described above, the temperature deviation of the crystal is zero.
Rather than, for example, 14.4MHz used in the current product
Is ± 5 ppm in the operating temperature range (−10 to 50 ° C.), but a product with a line frequency around 930 MHz causes a deviation of about 4.5 KHz in the local frequency.

In the present invention, the local frequency is changed one step at a time by controlling the PLLIC by utilizing the function of the control unit for detecting the number of error bits of the received signal, and the local frequency with the smallest number of error bits is determined. It is possible to detect and correct the local frequency shift due to the temperature to prevent the sensitivity from deteriorating.

Next, the processing operation of the radio selective call receiver having the above configuration will be described with reference to the flowchart shown in FIG.

First, the power of the radio selective calling receiver is turned on.
N is performed (step S301).

The control unit 5 reads the frequency division number V0 of the VCO from the EEPROM 4 (V = V0) (step S30).
2). Further, flags and variables described below are set in the control program used in the control unit 5.

A flag A for determining whether the received signal is the first reception after the power of the radio selective calling receiver is turned on, a variable B indicating the amount of change from the initial value of the VCO frequency dividing number, A flag C indicating whether the amount of change in B has increased or decreased, a flag D indicating whether the previous frequency division number of the VCO has been corrected from V0 to ±, a detected number of received words W, an error in the received signal. A variable H0 indicating the number of bits N and the ratio between W and N. Note that the flag A is A = 0 in the initial state, the variable B is B = 0 in the initial state, the flags C and D are +1 in the initial state, and W, N, and H0 are 0.
Are set respectively.

Next, the frequency division number of the VCO is notified to the phase synchronization unit 10 at V = V0 (step S303), and reception is performed (step S304).

The control unit 5 detects the number W of received words and the number N of error bits from the received signal (step S30).
5) Check whether the number N of error bits is 0 (step S306).

If the number of error bits is 0 (step S306 / YES), it is not necessary to change the local frequency, so it is checked whether the power has been turned off (step S307). If the power is turned off, the process ends (step S308). If the power is not turned off (step S307 / NO), the frequency division number of the VCO is notified to the phase synchronization unit 10 at the same V = V0 as before (step S307). Step S3
03), and prepare for the next reception (step S304).

If the number of error bits is not 0 (step S306 / NO), a ratio H = N / W is calculated from the detected number W of received words and the number N of error bits (step S3).
09), it is determined by the flag A whether or not the reception is the first reception after the power is turned on (step S310).

If the reception is the first reception after the power is turned on (step S310 / YES), the initial value of the variation is set to +1 in the present embodiment, so that B = B + 1 to increase the VCO frequency by one, and Since the amount is increased, C = + 1
(Step S311).

Next, the direction in which the previous VCO frequency division number was changed is confirmed (step S312). Since the current reception is the first reception, an initial value of +1 is given to D, and the frequency division number of the VCO at the next reception is changed from V0 to the + side by the value of B, and the direction of change is changed to D = +1 is stored (31
3). Then, the ratio H of the number of received words W and the number of error bits N is H
Is overwritten on H0 (step S315), and the frequency division number of the VCO is notified to the phase synchronization unit 10 as V = V0 + B. Then, it prepares for the next reception (step S304).

If it is not the first reception, D
= -1. In this case, the frequency division number V of the VCO is changed from V0 to the negative side (V = V0-B).
The direction of change is stored as D = -1 (step S31).
4).

If it is not the first reception after the power is turned on (step S310 / NO), it is checked whether or not the change amount of the variable B is set to 5 (step S31).
6). When changing the local frequency, it must be noted that if the amount of change is not limited, there is a possibility that data of a channel other than the own channel will be received and return will not be possible. Therefore,
In the present embodiment, a limit value is provided for a change in the frequency division number to prevent this problem. In this embodiment, the limit value is B =
Although it is set to 5, this value can be set arbitrarily.

If the amount of change has reached the limit value (step S316 / YES), at the time of the next reception, the amount of change is returned by one and the frequency division number of the VCO is given. Therefore, B = B-1 and C = -1 are set (step S31).
7) A flag D indicating whether the previous frequency division number of the VCO is on the plus side or the minus side of V0.
Is checked (step S312). When the previous frequency division number of the VCO is on the plus side of V0 (D = + 1)
(Step S312 / YES), the frequency division number V of the VCO at the next reception is changed from V0 to the plus side by the value of B (V = V0 + B), and the direction of the change is stored as D = + 1 (313). . If the previous frequency division number of the VCO is on the minus side of V0 (D = -1) (step S312)
/ NO), the frequency division number of the VCO at the next reception is changed from V0 to the minus side by the value of B (V = V0−
B) The direction of change is stored as D = -1. Then, the ratio H between the number W of received words and the number N of error bits is overwritten on H0 (step S315), and the frequency division number of the VCO is notified to the phase synchronization unit 10 with V. Then, it prepares for the next reception (step S304).

If the change amount of the variable B has not reached the limit value (step S316 / NO), the ratio H between the number W of received words and the number N of error bits is set to the ratio H0 between W and N at the previous reception. And (Step S318). If the ratio H of the number of error bits to the number of received words is equal to or less than the previous ratio H0 (step S318 / YES), H may be further reduced by changing the frequency division number in the same direction as the previous time. However, when the variable B = 0 (step S319 / YES), the polarity of the correction direction must be reversed. Therefore, D = D × −1 and B = B
+1 and C = + 1 (step S320), and step S320
It moves to 312.

If B = 0 is not satisfied (step S3
19 / NO), and checks a flag C indicating whether the previous change amount of B was increased or decreased (step S3).
21). If the previous change amount of B is increasing (C = + 1) (step S321 / YES), B = B + 1, C =
The value is set to +1 (step S311), and the process proceeds to step S312. When the previous change amount of B is decreased (C = −1) (step S321 / NO), B = B−1,
C = −1 (step S317), and step S312
Move to

Then, the value of D is +1 (previous VC
If the frequency division number of O is on the plus side than V0), the frequency division number of the VCO at the next reception is changed from V0 to the plus side by the value of B, and the direction of the change is stored as D = + 1. (Step S313). Also, the value of D is -1 (the previous V
If the frequency division number of CO is on the minus side of V0), the frequency division number of VCO at the next reception is changed from V0 to the minus side by the value of B, and the direction of the change is stored as D = -1. (Step S314). Then, the ratio H of the number W of received words and the number N of error bits is overwritten to H0 (step S31).
5) Notify the phase synchronizer 10 of the frequency division number of the VCO by V. Then, it prepares for the next reception (step S304).

If the ratio of the number of error bits N to the number of received words W is larger than the previous time (H0 <H) (step S318 / NO), it means that sensitivity has been degraded. It is necessary to return to the previous state. Therefore, the polarity of C is checked, and B is increased or decreased. If C is +1 (step S322 / Y
ES), the flow shifts to step S317. If C is −1 (step S322 / NO), step S311 is reached.
Move to

In the above-described embodiment, the variation of the local frequency due to the temperature can be corrected by detecting the number of error bits in the received signal and correcting the local frequency so as to minimize the number of error bits. , Signal degradation can be prevented.

Next, a second embodiment according to the present invention will be described with reference to FIG. Referring to FIG.
In this embodiment, an A / D converter 22 is added to the radio selective calling receiver of the first embodiment shown in FIG.

FIG. 5 is a block diagram showing the configuration of the radio unit 23 of the second embodiment shown in FIG.
An amplifier 30 that amplifies a received signal, a mixer 31 that converts a received signal to an intermediate frequency using the local frequency sent from the local unit 24, and a demodulation unit 33 that demodulates using the signal converted to the intermediate frequency from the mixer 31 including.

The demodulation unit 33 includes an amplifier 30, a mixer 31, and A
Constant voltage output circuit 3 serving as a power supply for the / D converter 22 and the like
2 inclusive.

In the first embodiment described above, the correction amount of the frequency of the VCO is fixed so as to be increased by one from V0 to the plus side when the first reception is performed after the power is turned on.

On the other hand, in the present embodiment, the difference between the current temperature and a predetermined reference temperature is detected, and the correction direction of the local frequency is determined.

In order to achieve this object, first, the temperature characteristics of the oscillation frequency of the crystal used as the reference clock of the local unit 24 are modeled. The oscillation frequency of the crystal used for the reference clock of the local unit generally has a temperature characteristic as shown in FIG. A representative value of this temperature characteristic is modeled.

Attention is also directed to the temperature characteristics of the constant voltage output circuit 32 included in the demodulation unit 33.

The constant voltage output circuit 32 has a temperature characteristic of -2 mV / .degree. C. as shown in FIG. 7 in order to prevent the operation of the amplifier and the mixer from changing with the temperature.

Using this temperature characteristic, a temperature difference (Vd) from a predetermined reference temperature is detected, and the correction direction is set in advance, so that the VCO correction amount in the case of the first reception after the power is turned on. To determine. The predetermined reference temperature is stored in the EEPROM in the inspection process (temperature control).

6 and 7, 0 ° C. to 25 ° C.
(0mV ≦ Vd <50mV), minus correction,
Less than 0 ° C or 25 ° C or more (Vd ≧ 50 mV, or Vd
When d <0 mV), it is set in the control program of the control unit so as to make a plus correction.

As described above, the current temperature is detected using the temperature characteristics of the constant voltage output circuit included in the demodulation unit, and the frequency at which the VCO is generated is determined in consideration of the temperature characteristics of the oscillation frequency of the crystal used for the reference clock. By determining whether to increase or decrease the frequency of the control signal, it is possible to reduce the deterioration of the receiving sensitivity due to the temperature deviation of the oscillation frequency of the crystal.

The above-described embodiment is a preferred embodiment of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention.

[0059]

As is apparent from the above description, in the present invention, the ratio of the number of error bits to the number of words received by the current received signal is larger than the ratio of the number of error bits to the number of words received by the previous received signal. In the case, from the frequency of the previous local frequency signal used to convert the frequency of the current reception signal to the predetermined frequency, the frequency of the previous two times used to convert the frequency of the previous reception signal to the predetermined frequency is used. A local frequency signal is generated by converting the frequency of the previous local frequency in the same direction as the conversion direction of the local frequency signal to the frequency, and the ratio of the number of error bits to the number of words received by the current received signal is determined by the previous received signal. If the ratio is smaller than the ratio of the number of error bits to the number of received words, the frequency of the local frequency signal two times before The control unit controls the local frequency generation unit to generate a local frequency signal obtained by converting the frequency of the previous local frequency in the same direction as the conversion direction of the frequency signal to the frequency, so that the number of error bits is minimized. It can be corrected to such a local frequency. Therefore, a change in local frequency due to a temperature change can be corrected, and sensitivity deterioration can be prevented.

When it is detected that the local frequency used for the conversion of the current reception signal has reached the upper limit frequency,
A local frequency signal having a frequency lower than the upper limit frequency is generated, and when it is detected that the local frequency used for the conversion of the current reception signal has reached the lower limit frequency, a local frequency signal having a higher frequency than the lower limit frequency is generated. Since the control means controls the local frequency generation means to generate the data, it is possible to prevent a problem that data of a channel other than the own channel is received and cannot be returned.

Further, there is provided a constant voltage output means having an output voltage having a linearity with respect to the temperature, and a demodulation means for demodulating the received signal. The control means is provided with a predetermined output voltage of the constant voltage output means. By controlling the frequency conversion direction of the local frequency signal generated by the local frequency generation means according to the difference between the reference voltage output from the constant voltage output means at the reference temperature, it is possible to correct local frequency fluctuations due to temperature changes, Sensitivity degradation can be prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a first embodiment of a radio selective call receiver according to the present invention.

FIG. 2 is a block diagram illustrating a configuration of a local unit.

FIG. 3 is a flowchart illustrating an operation example of a control unit.

FIG. 4 is a block diagram illustrating a configuration of a second embodiment of the radio selective call receiver according to the present invention.

FIG. 5 is a block diagram illustrating a configuration of a wireless unit according to a second embodiment.

FIG. 6 is a diagram showing a temperature deviation of the oscillation frequency of the crystal.

FIG. 7 is a diagram illustrating a temperature characteristic of a constant voltage output circuit.

FIG. 8 is a block diagram illustrating a configuration of a conventional wireless selective call receiver.

[Explanation of symbols]

 Reference Signs List 1 antenna 2 radio unit 3 local unit 4 control unit 5 EEPROM 6 RAM 7 ROM 8 display unit 9 VCO 10 phase synchronization unit 16 reference clock generation unit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5J103 AA08 BA02 BA06 CA06 CB02 DA05 DA08 DA17 DA32 DA38 DA46 GB04 HA04 HB02 HC03 JA04 JA18 5K020 DD22 DD23 GG07 GG10 GG11 GG21 5K067 AA23 BB22 CC11 DD46 EE02

Claims (8)

[Claims] 1. A radio selective calling receiver for selectively receiving a radio signal, a local frequency generation means for generating a local frequency signal for converting a frequency of the reception signal into a predetermined frequency, and a reception word of the reception signal. A receiving word number detecting means for detecting the number of error bits, an error bit number detecting means for detecting the number of error bits of the received signal, and an error rate calculating means for calculating a ratio of the number of error bits to the number of receiving words; Control means for controlling the generation means, wherein the control means has a ratio of the number of error bits to the number of words received by the current reception signal is greater than the ratio of the number of error bits to the number of words received by the previous reception signal In this case, the frequency of the previous local frequency signal used to convert the frequency of the current reception signal to a predetermined frequency is A local frequency signal is generated by converting the frequency of the previous local frequency in the same direction as the conversion direction to the frequency of the local frequency signal two times before, which was used to convert the frequency of the received signal to the predetermined frequency. If the ratio of the number of erroneous bits to the number of words received by the current received signal is smaller than the ratio of the number of erroneous bits to the number of words received by the previous received signal, the frequency of the local frequency signal two times before the previous The radio selective calling receiver, wherein the local frequency generation means is controlled to generate a local frequency signal obtained by converting the frequency of the previous local frequency in the same direction as the conversion direction of the local frequency signal to the frequency. . 2. The control means includes frequency range detecting means for detecting whether or not a local frequency used for conversion of a received signal at this time exceeds an upper limit frequency and a lower limit frequency. When detecting that the local frequency used for the conversion of the received signal this time has reached the upper limit frequency, the local frequency generator controls the local frequency generator to generate a local frequency signal having a frequency lower than the upper limit frequency. Then, when the frequency range detecting means detects that the local frequency used for the conversion of the current reception signal has reached the lower limit frequency, a local frequency signal having a frequency higher than the lower limit frequency is generated. 2. The radio selective calling receiver according to claim 1, wherein said local frequency generating means is controlled. 3. The control means has a detection means for detecting whether or not a received signal is a signal received for the first time after power-on of the radio selective calling receiver, and comprising a ratio of the number of error bits to a received signal. If the value is not 0 but the first reception after the power is turned on, the local frequency generation means is controlled to generate a local frequency whose frequency is raised by a predetermined amount from a preset reference frequency. The radio selective call receiver according to claim 1 or 2, wherein 4. The radio selective calling receiver includes constant voltage output means having an output voltage having a linearity with respect to temperature, and demodulation means for demodulating a received signal. The frequency conversion direction of a local frequency signal generated by the local frequency generation means is controlled by a difference between an output voltage of the output means and a reference voltage output by the constant voltage output means at a predetermined reference temperature. The radio selective call receiver according to any one of claims 1 to 3. 5. A local frequency generator, comprising: a voltage controlled oscillator for oscillating and outputting a local frequency signal for converting a frequency of a received signal into a predetermined frequency; and a reference clock for generating a reference clock signal of a predetermined frequency. Generating means; and a first frequency divider for dividing a local frequency signal output from the voltage controlled oscillator by a frequency division number set by the control means.
Frequency dividing means; second frequency dividing means for dividing a reference clock signal generated by the reference clock generating means by a predetermined frequency dividing number; and a local frequency divided by the first frequency dividing means. Phase comparing means for comparing the phase of the signal with the reference clock signal divided by the second frequency dividing means and outputting a phase difference signal according to the phase difference; 5. A voltage supply means for outputting a voltage value corresponding to a phase difference to said voltage controlled oscillation means.
Wireless selective call receiver according to the paragraph. 6. A method for generating a local frequency in a radio selective calling receiver for selectively receiving a radio signal, comprising: a reception word number detection step of detecting a reception word number of the reception signal; The number of error bits to be detected, the error rate calculation step to calculate the ratio of the number of error bits to the number of received words, and the ratio of the number of error bits to the number of words received by the current received signal is the number of words received by the previous received signal From the frequency of the previous local frequency signal used to convert the frequency of the current received signal to the predetermined frequency, the frequency of the previous received signal is changed to the predetermined frequency. The local frequency of the previous local frequency in the same direction as the conversion direction to the frequency of the local frequency signal two times before used to convert the A first local frequency generation step of generating a local frequency signal whose wave number has been converted, wherein the ratio of the number of error bits to the number of words received by the current reception signal is greater than the ratio of the number of error bits to the number of words received by the previous reception signal. When the frequency is smaller, a second local frequency signal is generated by converting the frequency of the previous local frequency in the same direction as the conversion direction from the frequency of the local frequency signal two times before to the frequency of the previous local frequency signal. And a local frequency generating step. 7. A frequency range detecting step for detecting whether or not a local frequency used for conversion of the current received signal exceeds an upper limit frequency and a lower limit frequency; A third local frequency generating step of generating a local frequency signal having a frequency lower than the upper limit frequency when detecting that the local frequency used for the conversion has reached the upper limit frequency; and the frequency range detecting step. A fourth local frequency generation step of generating a local frequency signal having a frequency higher than the lower limit frequency when detecting that the local frequency used for the conversion of the current reception signal has reached the lower limit frequency. 7. The local frequency generation method according to claim 6, comprising: 8. A detecting step for detecting whether or not a received signal is a signal received for the first time after power-on of the radio selective calling receiver, and after the power-on when the ratio of the number of error bits to the received signal is not 0 and And a fifth local frequency generating step of generating a local frequency whose frequency is raised by a predetermined amount from a preset reference frequency when receiving for the first time. The described local frequency generation method.