JP4107258B2 - Radio receiver, radio clock, and repeater - Google Patents

Description

  The present invention relates to a radio wave receiver, a radio timepiece, and a repeater.

  Currently, in each country (for example, Japan, the United States, Germany, etc.), a time code, that is, a longwave standard radio wave including a time code is transmitted. In Japan (Japan), two transmitting stations (Fukushima Prefecture and Saga Prefecture) transmit 40 kHz and 60 kHz long wave standard radio waves that are amplitude-modulated with a time code in a format as shown in FIG. According to FIG. 18, the time code is transmitted every time the minute digit of the correct time is updated, that is, in a frame of one cycle of 60 seconds.

  By the way, a so-called radio timepiece that receives such a standard radio wave and corrects date and time data of a clock circuit has been put into practical use. Various noises are mixed in the standard radio wave that is actually received by the radio clock, but not only the noise outside the radio clock in the transmission process from the transmitting station to the radio clock, but also the signal generated by the circuit inside the radio clock. Noise may be mixed in. For example, a common signal or a segment signal output from a display control signal generation unit such as a display driver, an electric signal generated by turning on / off a backlight of the display unit, noise is generated from the display device and the periphery of the display device, or is extremely short. Noise is generated by a control signal for controlling the chrono function for measuring the time interval. For this reason, various methods have been devised to reduce the mixing of noise generated inside the radio timepiece.

  For example, according to Patent Document 1, control of prohibiting the reception of the standard radio wave while the chrono function is operating is prohibited while the standard radio wave is being received and the operation of the chrono function as a noise generation source is prohibited. A watch with a radio wave correction function is disclosed.

Further, Patent Document 2 discloses a wristwatch type communication device in which the inside of a main body is divided by a shielding plate, a transmitting circuit and a receiving device are arranged on one side, and a digital circuit serving as a noise generation source is arranged on the other side.
JP-A-8-201546 Japanese Patent Laid-Open No. 4-211198

  However, the timepiece with a radio wave correction function of Patent Document 1 can execute only one of the execution of the chrono function and the reception of the standard radio wave.

  Moreover, in the wristwatch-type communication apparatus of Patent Document 2, it is possible to reduce noise mixing, but it is difficult to prevent it. For this reason, there is a possibility of being affected by noise in the reproduction of the received signal. In addition, there is a problem that restrictions are imposed on the arrangement of components and circuits.

  The present invention has been made in view of the above-described problems, and the object of the present invention is to provide a special member such as a shielding plate without impeding the execution of other device operations inside the receiving apparatus. The received signal can be reproduced without being affected by noise generated inside the receiving apparatus.

In order to solve the above problems, the invention described in claim 1
In a radio wave receiving apparatus (for example, the radio wave receiving apparatus 62 in FIGS. 1 and 2) including a receiving unit that receives a reception signal with an antenna and a display unit that displays information,
Noise timing signal output means (for example, FIG. 5) that detects an edge portion of a display control signal having a pulse waveform shape that is output for display control of the display portion and outputs a noise timing signal synchronized with the generation timing of the edge portion. 1, the noise timing signal generator 86) of FIG.
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal, converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal (for example, the detection circuit 626 in FIG. 2). )When,
Amplification operation stop control means for controlling to temporarily stop the control operation for amplifying the received signal for a predetermined time in synchronization with the noise timing signal output from the noise timing signal output means (For example, the RF amplification circuit 620 in FIG. 2; step S13 in FIG. 5);
Smoothing output means for smoothing and outputting the output detection signal when a signal for which the control operation for amplifying the received signal is stopped by the control of the amplification operation stop control means is output as the detection signal ( For example, the third filter circuit 627) of FIG.
It is characterized by having.

According to the first aspect of the present invention, the noise timing signal generation / output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. Then, in synchronization with the noise timing signal, the amplification operation stop control means stops the control operation for amplifying the received signal for a predetermined time. For this reason, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the control operation for amplifying the received signal is stopped for a predetermined time in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence due to the noise generated from the edge portion of the display control signal. The amplified received signal is converted into an intermediate frequency signal, and after a detection signal based on the intermediate frequency signal is output, it is smoothed and output by a smoothing output means. In this way, the smoothed output means smooths the signal that has become no signal due to the stop of the control operation for amplifying the received signal, thus preventing the stop of the control operation for amplification from affecting the reproduction of the received signal. can do.

The invention according to claim 2
In a radio wave receiving apparatus (for example, the radio wave receiving apparatus 62 in FIGS. 1 and 8) including a receiving unit that receives a reception signal with an antenna and a display unit that displays information,
Noise timing signal output means (for example, FIG. 5) that detects an edge portion of a display control signal having a pulse waveform shape that is output for display control of the display portion and outputs a noise timing signal synchronized with the generation timing of the edge portion. 8 noise timing signal generator 86),
Noise timing signal smoothing means (for example, a low-pass filter 636 in FIG. 14) for smoothing and outputting the noise timing signal;
Based on the signal output by the noise timing signal smoothing means, signal short-circuit control means (for example, the short-circuit circuit 638 in FIG. 14) that short-circuits the antenna and dissipates the energy of the received signal for a predetermined time. )When,
It is characterized by having.

According to the second aspect of the present invention, the noise timing signal is smoothed, and based on the smoothed signal, a predetermined time antenna is short-circuited to dissipate the energy of the received signal. Thereby, the noise which generate | occur | produces in the edge part of a noise timing signal can be reduced. Therefore, it is possible to prevent the influence of noise generated from the noise timing signal.

The invention according to claim 3
In a radio wave receiving apparatus (for example, the radio wave receiving apparatus 62 in FIGS. 1 and 9) including a receiving unit that receives a reception signal with an antenna and amplifies the signal with a gain according to a gain control signal and a display unit that displays information.
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal, converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal (for example, the detection circuit 626 in FIG. 9). )When,
Noise timing signal output means (for example, FIG. 5) that detects an edge portion of a display control signal having a pulse waveform shape that is output for display control of the display portion and outputs a noise timing signal synchronized with the generation timing of the edge portion. 9 noise timing signal generator 86),
In synchronization with the noise timing signal output from the noise timing signal output means, a gain control signal output means for outputting a signal for attenuating the gain from the gain control signal for a predetermined time (for example, AGC in FIG. 9). Circuit 628b);
Smoothing output means for smoothing and outputting the detection signal output by detecting the intermediate frequency signal when a signal for attenuating the gain is output from the gain control signal under the control of the gain control signal output control means ( For example, the third filter circuit in FIG. 9 is provided.

According to the third aspect of the present invention, the noise timing signal generation / output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. The gain control signal output means outputs a gain control signal for attenuating the gain in synchronization with the noise timing signal. The received signal is attenuated with a gain according to the gain control signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the received signal is attenuated in synchronization with the noise timing signal. Is not propagated. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

The invention according to claim 4
In a radio wave receiving apparatus (for example, the radio wave receiving apparatus 62 in FIGS. 1 and 10) including a receiving unit that receives and amplifies a received signal with an antenna and outputs a detection signal and a display unit that displays information.
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal, converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal (for example, the detection circuit 626 in FIG. 10). )When,
Noise timing signal output means (for example, FIG. 5) that detects an edge portion of a display control signal having a pulse waveform shape that is output for display control of the display portion and outputs a noise timing signal synchronized with the generation timing of the edge portion. 10 noise timing signal generators 86),
In synchronization with the noise timing signal output from the noise timing signal output means, signal control means for making the signal output from the detection signal non-signal for a predetermined time (for example, the noise elimination circuit of FIG. 10). 629),
Smoothing output means (for example, the third filter circuit of FIG. 10) for smoothing and outputting the output detection signal when the signal output from the detection signal becomes no signal under the control of the signal control means. 627),
It is characterized by having.

According to a fourth aspect of the present invention, the noise timing signal generation / output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. Then, in synchronization with the noise timing signal, the signal control means outputs the detection signal as no signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the signal control means makes no detection signal in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

The invention according to claim 5
A radio wave receiving apparatus (for example, including a receiving unit that synthesizes a signal obtained by amplifying a received signal received by an antenna with a predetermined oscillation signal, converts it to an intermediate frequency signal and outputs it as a detection signal, and a display unit that displays information 1 and FIG. 13, the radio wave receiving device 62)
Noise timing signal output means (for example, FIG. 5) that detects an edge portion of a display control signal having a pulse waveform shape that is output for display control of the display portion and outputs a noise timing signal synchronized with the generation timing of the edge portion. 13 noise timing signal generators 86),
Synchronous with the noise timing signal output from the noise timing signal output means, intermediate frequency signal control means for making the intermediate frequency signal non-signal for a predetermined time (for example, the noise elimination circuit 629a in FIG. 13). When,
Smoothing output means (for example, FIG. 13) that smoothes and outputs the detection signal output by detecting the intermediate frequency signal when the intermediate frequency signal is set to no signal by the control of the intermediate frequency signal control means in the previous period. A third filter circuit 627);
It is characterized by having.

According to the fifth aspect of the present invention, the noise timing signal generation / output unit generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. The intermediate frequency signal control means outputs the intermediate frequency signal as no signal in synchronization with the noise timing signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the intermediate frequency signal control means makes the intermediate frequency signal non-synchronized in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

The invention according to claim 6
The radio wave receiver according to any one of claims 1 to 5 ,
Display control signal generation means (for example, display control signal generation unit 80 in FIG. 1) for generating a display control signal having a pulse waveform shape for display control of the display unit;
It further comprises time delay control means (for example, delay circuit unit 82 in FIG. 1) for delaying display control by the display control signal generated by the display control signal generation means for a predetermined time. .

According to the invention described in claim 6 , it is needless to say that the same effect as in the invention described in any one of claims 1 to 5 can be obtained, and the display control signal generated by the display control signal generating means. The display control by the display unit can be delayed for a predetermined time. Accordingly, the noise timing signal generation / output unit generates the noise timing signal earlier than the display operation of the display unit due to the delay time given by the time delay control unit. For this reason, it is possible to reliably prevent noise from occurring due to the operation of the display control means.

The radio timepiece according to claim 7 is:
The radio wave receiver according to any one of claims 1 to 6 ,
Time code generating means for generating a standard time code based on a standard radio signal included in a signal output from the radio wave receiver (for example, the time code conversion unit 70 in FIG. 1);
A time counting means for counting the current time (for example, the time measuring circuit unit 50 in FIG. 1);
The present invention is characterized by comprising correction means (for example, the CPU 10 in FIG. 1) for correcting current time data counted by the time counting means based on the standard time code generated by the time code generating means.

According to the invention described in claim 7, it can be realized radio clock same effect as described in any one of claims 1 to 6 is obtained.

The repeater according to claim 8 is:
The radio wave receiver according to any one of claims 1 to 6 ,
Time code generating means (for example, the time code converting unit 70 in FIG. 16) for generating a standard time code based on a standard radio signal included in a signal output from the radio wave receiver;
Transmission means (for example, the transmission unit 100 in FIG. 16) for transmitting the standard time code generated by the time code generation means;
It is characterized by having.

According to the invention described in claim 8 , it is possible to realize a repeater capable of obtaining the same effect as that of the invention described in any one of claims 1-6 .

According to the first aspect of the present invention, the noise timing signal generation / output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. Then, in synchronization with the noise timing signal, the amplification operation stop control means stops the control operation for amplifying the received signal for a predetermined time. For this reason, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the control operation for amplifying the received signal is stopped for a predetermined time in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal. The amplified received signal is converted into an intermediate frequency signal, and after a detection signal based on the intermediate frequency signal is output, it is smoothed and output by a smoothing output means. In this way, the smoothed output means smooths the signal that has become no signal due to the stop of the control operation for amplifying the received signal, thus preventing the stop of the control operation for amplification from affecting the reproduction of the received signal. can do.

According to the second aspect of the present invention, the noise timing signal is smoothed, and based on the smoothed signal, a predetermined time antenna is short-circuited to dissipate the energy of the received signal. Thereby, the noise which generate | occur | produces in the edge part of a noise timing signal can be reduced. Therefore, it is possible to prevent the influence of noise generated from the noise timing signal.

According to the invention described in claim 3, the noise timing signal generation output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. The gain control signal output means outputs a gain control signal for attenuating the gain in synchronization with the noise timing signal. The received signal is attenuated with a gain according to the gain control signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the received signal is attenuated in synchronization with the noise timing signal. Is not propagated. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

According to a fourth aspect of the present invention, the noise timing signal generation / output means generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. Then, in synchronization with the noise timing signal, the signal control means outputs the detection signal as no signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the signal control means makes no detection signal in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

According to the fifth aspect of the present invention, the noise timing signal generation / output unit generates a noise timing signal synchronized with the generation timing of the edge portion of the display control signal. The intermediate frequency signal control means outputs the intermediate frequency signal as no signal in synchronization with the noise timing signal. Therefore, even if a radio wave mixed with noise generated at the edge of the display control signal is received, the intermediate frequency signal control means makes the intermediate frequency signal non-synchronized in synchronization with the noise timing signal. Is not propagated inside the radio wave receiver. Therefore, it is possible to prevent the influence caused by the noise generated from the display control signal.

According to the invention described in claim 6 , the display control of the display unit by the display control signal generated by the display control signal generating means is delayed for a predetermined time. Therefore, the noise timing signal generation / output unit generates the noise timing signal earlier than the actual operation of the display unit due to the delay time given by the time delay control unit. For this reason, it is possible to reliably prevent noise from occurring due to the operation of the display control means.

According to the invention described in claim 7, it can be realized radio clock same effect as described in any one of claims 1 to 6 is obtained.

According to the invention described in claim 8 , it is possible to realize a repeater capable of obtaining the same effect as that of the invention described in any one of claims 1-6 .

  Hereinafter, the best mode for carrying out the present invention will be described with reference to FIGS. In the following embodiments, a radio timepiece and a repeater to which the present invention is applied will be described as an example. However, the present invention can be appropriately applied to any other apparatus for receiving radio waves.

  FIG. 1 is a block diagram showing an example of a circuit configuration of a radio timepiece 1 to which the present invention is applied. Referring to FIG. 1, a radio timepiece 1 includes a CPU (Central Processing Unit) 10, a RAM (Random Access Memory) 20, a ROM (Read Only Memory) 30, an input unit 40, a clock circuit unit 50, an oscillation circuit unit 52, and a radio wave. A receiving device 62 is provided. The radio wave receiving device 62 includes a reception control unit 60, a time code conversion unit 70, a display device 88, and a noise timing signal generation unit 86, and excludes the oscillation circuit unit 52 and the noise timing signal generation unit 86. Each unit is connected by a bus 90.

  The CPU 10 reads out various programs stored in the ROM 30 in accordance with a predetermined timing or an operation signal input from the input unit 40, expands the program in the RAM 20, and gives instructions and data to each functional unit based on the program. For example. In particular, the CPU 10 controls the reception control unit 60 at predetermined time intervals, for example, executes standard radio wave reception processing, and is counted by the time measuring circuit unit 50 based on the standard time code input from the time code conversion unit 70. In addition to correcting the current time data, various controls such as outputting display data based on the corrected time code to the display control signal generator 80 and updating the display time to be displayed on the display device 88 are performed.

  The RAM 20 is used for storing data processed by the CPU 10 under the control of the CPU 10 and outputting the stored data to the CPU 10. The ROM 30 mainly stores system programs and application programs related to the radio timepiece 1.

  The input unit 40 includes a switch for causing the radio timepiece 1 to execute various functions. When these switches are operated, an operation signal for the corresponding switch is output to the CPU 10.

  The timer circuit unit 50 counts signals input from the oscillator circuit unit 52 to obtain current time data and the like. Then, the current time data is output to the CPU 10. The oscillation circuit unit 52 is a circuit that always outputs a signal having a constant frequency.

  The reception control unit 60 cuts unnecessary frequency components of the standard radio wave received by the antenna, extracts a corresponding frequency signal, detects this frequency signal, and outputs it to the time code conversion unit 70 as a time correction signal h.

  Based on the time correction signal h output from the reception control unit 60, the time code conversion unit 70 generates a standard time code including data necessary for a clock function such as a standard time code, an integrated day code, and a day code. , Output to the CPU 10.

  The display device 88 is configured by, for example, a segment type display, and includes a display control signal generation unit 80 and a delay circuit unit 82. The display device 88 may be configured by a small liquid crystal display such as an LCD (Liquid Crystal Display).

  The display control signal generation unit 80 controls display data input from the CPU 10 to the display device 88 to display various screens. Further, the display control signal generation unit 80 outputs a display control signal a of a liquid crystal drive signal composed of, for example, a segment signal or a common signal to the noise timing signal generation unit 86.

  FIG. 4A is a diagram illustrating a waveform of the display control signal a using the liquid crystal drive signal as an example. According to the figure, the display control signal a is a signal having a pulse waveform that is displaced in a fixed time unit as a control signal for driving and controlling the display device 88.

  The delay circuit unit 82 is configured by an inverter element or the like. For example, the delay circuit unit 82 delays propagation of the display control signal a generated by the display control signal generation unit 80 by a predetermined time, and displays a liquid crystal driving circuit unit (not shown) inside the display device 88. The control of the display device 88 by the display control signal generation unit 80 is delayed for a predetermined time. Depending on the delay time added by the delay circuit unit 82, the radio wave receiving device 62 synchronizes with the display control signal a so as to synchronize with the timing at which the received signal is not based on the edge pulse signal b (described later). In addition, synchronization with the generation timing of noise generated around the display device 88 is taken. The display device 88 may be configured without the delay circuit unit 82.

  The noise timing signal generation unit 86 detects an edge portion of the display control signal a input from the display control signal generation unit 80, generates an edge pulse signal b synchronized with the generation timing of the edge portion, and the reception control unit 60. Output to.

  FIG. 4B shows the waveform of the edge pulse signal b. According to the figure, the edge pulse signal b is generated as an impulse waveform having a shorter ON time than the pulse waveform of the display control signal a shown in FIG. The pulse width Pw of the edge pulse signal b is, for example, until the amplitude of the noise signal (high frequency signal) c generated so as to be synchronized with the edge portion of the display control signal a falls within a predetermined ratio (for example, about 20%). This corresponds to time (elapsed time from time t1 to t2). The pulse width Pw may be set to a suitable value as appropriate.

Embodiment 1
Next, Embodiment 1 of the radio timepiece 1 will be described.
FIG. 2 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62 using the superheterodyne method according to the first embodiment. According to the figure, the reception control unit 60 includes an antenna ANT, an RF amplification circuit 620, a first filter circuit 621, a frequency conversion circuit 622, a local oscillation circuit 623, a second filter circuit 624, an IF amplification circuit 625, and a detection circuit 626. And a third filter circuit 627 and an AGC (Auto Gain Control) circuit 628.

  The antenna ANT is configured by a bar antenna or the like. The antenna ANT receives the standard radio wave d, converts the received radio wave into an electric signal (hereinafter referred to as “reception signal” e), and outputs the electric signal to the RF amplification circuit 620.

  The RF amplification circuit 620 receives the reception signal e output from the antenna ANT, the RF control signal k1 output from the AGC circuit 628, and the edge pulse signal b output from the noise timing signal generation unit 86. . The RF amplifier circuit 620 amplifies (or attenuates) the received signal e with an amplification degree corresponding to the RF control signal k 1 and outputs the amplified signal to the first filter circuit 621.

  When the RF amplifier circuit 620 detects the edge pulse signal b, the RF amplifier circuit 620 performs signal output operation in synchronization with the detected edge pulse signal b during the ON time of the edge pulse signal b, that is, the time corresponding to the pulse width Pw. Stop. Therefore, the output signal of the RF amplifier circuit 620 (hereinafter referred to as “intermittent signal” f) is output as a no-signal state for a time synchronized with the edge pulse signal b.

  The first filter circuit 621 is configured by a low-pass filter or the like. The intermittent signal f output by the RF amplifier circuit 620 is input to the first filter circuit 621. Then, the first filter circuit 621 allows a frequency in a predetermined range to pass through the input intermittent signal f, cuts off a frequency component outside the range, and outputs it.

  The frequency conversion circuit 622 receives the signal output from the first filter circuit 621 and the local oscillation frequency signal output from the local oscillation circuit 623. The frequency conversion circuit 622 combines the two input signals, converts the signal input from the first filter circuit 621 into an intermediate frequency, and outputs the intermediate frequency.

  The second filter circuit 624 is configured by a band pass filter or the like. The signal output from the frequency conversion circuit 622 is input to the second filter circuit 624. Then, the input signal is allowed to pass through a predetermined range of frequencies centering on the intermediate frequency, and the frequency component outside the range is cut off and output.

  The IF amplifier circuit 625 receives the signal output from the second filter circuit 624 and the IF control signal k2 output from the AGC circuit 628. The IF amplifier circuit 625 amplifies (or attenuates) the signal input from the second filter circuit 624 with an amplification degree corresponding to the IF control signal k2, and outputs the signal to the detection circuit 626 as an intermediate frequency signal if.

  The detection circuit 626 is synchronously detected by, for example, a PLL (Phase Locked Loop) circuit or the like, but can also be realized by a detection method such as envelope detection or peak detection. The detection circuit 626 receives the intermediate frequency signal if output from the IF amplification circuit 625, detects the intermediate frequency signal if, and outputs the detection signal g to the third filter circuit 627 and the AGC circuit 628.

  The third filter circuit 627 is configured by a low-pass filter having a sufficiently large time constant. The detection signal g output from the detection circuit 626 is input to the third filter circuit 627. Then, the third filter circuit 627 smoothes the input detection signal g and outputs it to the time code conversion unit 70 as a time correction signal h.

The AGC circuit 628 receives the detection signal g output from the detection circuit 626. Here, the AGC detection may be performed by inputting the intermediate frequency signal if output from the IF amplification circuit 625 to the AGC circuit 628.
The AGC circuit 628 uses the RF control signal k1 and the IF control signal k2 as gain control signals for adjusting the amplification degrees of the RF amplification circuit 620 and the IF amplification circuit 625 according to the strength (signal level magnitude) of the detection signal g. Is output. Here, the amplification degrees of the RF amplification circuit 620 and the IF amplification circuit 625 are adjusted according to the intensity of the radio wave received by the antenna ANT. For example, the AGC circuit 628 first controls the amplification degree of the IF amplifier circuit 625 by the IF control signal k2. However, when the level of the signal input to the IF amplifier circuit 625 is large and the attenuation in the IF amplifier circuit 625 is insufficient, the amplification of the RF amplifier circuit 620 is also adjusted by the RF control signal k1.

Next, the radio wave reception process of the radio timepiece 1 will be described together with the schematic waveform of each signal.
First, the display control signal generation unit 80 generates a display control signal a (FIG. 4A) for controlling the driving of the display device 88, and the delay circuit unit 82 applies the signal to each unit in the display device 88. The application of the display control signal a is delayed for a predetermined time, and the driving of the display device 88 is delayed for a predetermined time. In addition, the display control signal a is output to the noise timing signal generation unit 68.

  The noise timing signal generator 86 generates an edge pulse signal b (FIG. 4B) from the input display control signal a. Specific processing of the noise timing signal generation unit 86 will be described using the flowchart shown in FIG. 3 and the schematic waveforms of the signals shown in FIG.

  When the display control signal a (FIG. 4A) output from the display control signal generator 80 is input to the noise timing signal generator 86 (step S1), the edge portion (rising edge and A falling edge, for example, a portion corresponding to times t1 and t3 shown in FIG. 4A is detected (step S3).

  Next, an edge pulse signal b (FIG. 4B) synchronized with the edge portion of the display control signal a is generated with a predetermined pulse width Pw (step S5) and output to the RF amplifier circuit 620 (step S7). FIG. 4C shows the waveform of the display device 88 and the noise signal c generated around the display device 88 so as to be synchronized with the display control signal a, and the pulse width Pw is the noise signal shown in FIG. This corresponds to the elapsed time from time t1 to time t2.

  An outline of an ideal waveform of the standard radio wave d is shown in FIG. An outline of the waveform of the reception signal e received by the antenna ANT with respect to the standard radio wave d is as shown in FIG. The received signal e is mixed with a noise signal c (see FIG. 4C).

  The RF amplifying circuit 620 amplifies the received signal e mixed with noise with an amplification degree according to the RF control signal k1, and temporarily stops the operation of the circuit for a certain period of time in synchronization with the edge pulse signal b. A specific operation of the RF amplifier circuit 620 will be described with reference to a flowchart shown in FIG. 5 and schematic waveforms of signals shown in FIG.

  When detecting the edge pulse signal b (FIG. 6C) (step S11: Yes), the RF amplifier circuit 620 stops the operation of the circuit for a time corresponding to the pulse width Pw of the edge pulse signal b (step S11). S13). Then, a signal including a no-signal state while the circuit operation is stopped is output to the first filter circuit 621 as the intermittent signal f (FIG. 6D) (step S15).

  If the edge pulse signal b is not detected in step S11 (step S11: No), the reception signal e is amplified (or attenuated) in accordance with the RF control signal k1 (step S17), and the intermittent signal f is obtained. Output to the first filter circuit 621 (step S15).

  FIG. 6D is a schematic waveform of the intermittent signal f output from the RF amplifier circuit 620. According to the figure, during the time corresponding to the pulse width Pw of the edge pulse signal b, that is, between the time t1 and the time t2 and between the time t3 and the time t4, the noise portion of the received signal e (FIG. 6 (b ) From time t1 to time t2, and from time t3 to time t4) are brought into a no-signal state by the operation of the RF amplifier circuit 620 being stopped.

  The first filter circuit 621 passes the frequency in a predetermined range of the input intermittent signal f, cuts off the frequency component outside the range, and outputs the frequency component to the frequency conversion circuit 622.

  The frequency conversion circuit 622 synthesizes the signal input from the first filter circuit and the local oscillation frequency signal input from the local oscillation circuit 623, converts the signal to an intermediate frequency, and outputs the intermediate frequency to the second filter circuit 624.

  The second filter circuit 624 allows the signal input from the frequency conversion circuit 622 to pass a predetermined range of frequencies centering on the intermediate frequency, blocks out-of-range frequency components, and outputs the signal to the IF amplifier circuit 625.

  The IF amplifier circuit 625 amplifies the input signal with an amplification degree corresponding to the IF control signal k2, and outputs the amplified signal to the detection circuit 626 as an intermediate frequency signal if.

  The detection circuit 626 detects the input intermediate frequency signal if and outputs a detection signal g. Specifically, the baseband signal (the outer edge j of the intermittent signal f (intermediate frequency signal if) shown in FIG. 6D) that is an amplitude component is detected from the intermediate frequency signal if. Then, the positive component of the amplitude component of the intermediate frequency signal if (above the center line L1), the negative component (below the center line L1), or the sum of the absolute value of the positive component and the absolute value of the negative component is detected signal. It outputs to the 3rd filter circuit 627 as g (refer Fig.7 (a)).

  The third filter circuit 627 performs a process of smoothing the input detection signal g and outputs it to the time code conversion unit 70. FIG. 7A shows the outline of the waveform of the detection signal g, and FIG. 7B shows the outline of the waveform of the time correction signal h output from the third filter circuit 627. According to FIG. 7B, since the time constant of the third filter circuit 627 is sufficiently large, the waveform portion that is in a no-signal state such as between time t1 and time t2 is smoothed.

  As described above, according to the first embodiment, the noise timing signal generation unit 86 generates the edge pulse signal b based on the display control signal a output from the display control signal generation unit 80. Then, the RF amplifier circuit 620 to which the edge pulse signal b is input stops the operation of the circuit for a certain time in synchronization with the edge pulse signal b. Therefore, even if the noise signal c generated around the display device 88 and the display device 88 is mixed from the antenna ANT, the portion where the noise signal c is mixed due to the stop of the RF amplifier circuit 620 for a certain time is the RF amplifier circuit 620. It is not propagated to the subsequent circuit. For this reason, the signal of the part in which the noise signal c is mixed is not included in the detection signal g finally output by the radio wave receiving device 62, and reception deterioration due to noise generated from the inside of the main body can be prevented.

  In addition, the intermittent signal f output by the RF amplifier circuit 620 is subjected to various processes and input to the detection circuit 626 as an intermediate frequency signal if. The detection circuit 626 outputs a detection signal g (baseband signal) based on the input intermediate frequency signal if, and the third filter circuit 627 performs a process of smoothing the input detection signal g. . Therefore, the detection signal g includes a no-signal state due to the operation stop of the RF amplifier circuit 620 for a certain time, but the no-signal portion is corrected according to the signals before and after the smoothing by the third filter circuit 627. Can do.

  Furthermore, although the signal level of the time correction signal h is lower than that of the detection signal g, there is almost no deterioration in the S / N ratio, and there is no effect on the reproduction of the date / time data included in the time correction signal h. .

  Further, the delay circuit unit 82 delays the control of the display device 88 by the display control signal a for a predetermined time. In other words, the display circuit a is input to the noise timing signal generator 86 earlier by the delay circuit unit 82 than the display device 88 is controlled by the signal. Therefore, the noise timing signal generation unit 86 can generate the edge pulse signal b prior to the actual circuit operation of the display device 88 based on the delay time provided by the delay circuit unit 82. For this reason, it is possible to more reliably prevent noise from occurring due to the circuit operation of the display control signal generation unit 80.

  In the first embodiment, the circuit for controlling the operation by the edge pulse signal b is the RF amplifier circuit 620. However, the circuit is not limited to this, and can be changed as appropriate. In the following, modifications will be described in which the circuit for controlling the operation by the edge pulse signal b is the switch circuit SW and the AGC circuit 628b.

(Modification 1)
A first modification of the radio timepiece 1 according to the first embodiment will be described. The radio-controlled timepiece 1 in Modification 1 has a configuration in which the reception control unit 60 of the first embodiment shown in FIG. 1 is replaced with a reception control unit 60a.

  FIG. 8 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62 in the first modification. The reception control unit 60a in Modification 1 has the same configuration as that in which the switch circuit SW is provided between the antenna ANT and the RF amplifier circuit 620 in FIG. Further, the edge pulse signal b output from the noise timing signal generator 86 is output to the switch circuit SW. In addition, the same code | symbol is attached | subjected to the component same as the electromagnetic wave receiver 62 shown and demonstrated in FIG. 2 in Embodiment 1, and the description is abbreviate | omitted.

  According to FIG. 8, the noise timing signal generator 86 outputs the edge pulse signal b to the switch circuit SW. The switch circuit SW is normally in the OFF state. However, when the edge pulse signal b is detected, the switch circuit SW is in the ON state for a time synchronized with the edge pulse signal b, that is, a time corresponding to the pulse width Pw. Become.

  As described above, according to the first modification, the edge pulse signal b output from the noise timing signal generator 86 is input to the switch circuit SW. Then, the switch circuit SW is turned on in synchronization with the pulse width Pw of the edge pulse signal b. Therefore, even if the noise signal c generated around the display device 88 and the display device 88 is mixed from the antenna ANT, the switching between the antenna ANT and the RF amplifier circuit 620 is short-circuited by switching the switch circuit SW to the ON state. The Thereby, it is possible to prevent the energy of the noise signal c mixed in the antenna ANT from being dissipated and propagating from the RF amplifier circuit 620 to a circuit subsequent to the RF amplifier circuit 620, and the same effect as in the first embodiment can be obtained.

(Modification 2)
Next, a second modification of the radio timepiece 1 according to the first embodiment will be described. The radio timepiece 1 in Modification 2 has a configuration in which the reception control unit 60 of the first embodiment illustrated in FIG. 1 is replaced with a reception control unit 60b.

  FIG. 9 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62 according to the second modification. The reception control unit 60b according to Modification 2 has a configuration in which the AGC circuit 628 in FIG. 2 is replaced with an AGC circuit 628b. Further, the edge pulse signal b output from the noise timing signal generator 86 is output to the AGC circuit 628b. In addition, the same code | symbol is attached | subjected to the component same as the electromagnetic wave receiver 62 shown and demonstrated in FIG. 2 in Embodiment 1, and the description is abbreviate | omitted.

  According to FIG. 9, the noise timing signal generator 86 outputs the edge pulse signal b to the AGC circuit 628b.

  The AGC circuit 628b performs the same operation as that of the first embodiment. When the edge pulse signal b is detected, the AGC circuit 628b synchronizes with the edge pulse signal b to turn on the edge pulse signal b, that is, a time corresponding to the pulse width Pw. Meanwhile, instead of the RF control signal k1 and the IF control signal k2, the RF control signal k3 and the IF control signal k4 are output. The RF control signal k3 and the IF control signal k4 attenuate the output signals of the RF amplifier circuit 620 and the IF amplifier circuit 625. The RF amplifying circuit 620 and the IF amplifying circuit 625 attenuate and input the input signal with attenuation degrees according to the RF control signal k3 and the IF control signal k4, respectively.

  As described above, according to the second modification, even if the noise signal c generated around the display device 88 and the display device 88 is mixed from the antenna ANT, the noise signal c is mixed by the RF amplification circuit 620 and the IF amplification circuit 625. Since the portion of the standard radio wave d is attenuated, the same effect as in the first embodiment can be obtained.

[Embodiment 2]
Next, a second embodiment of the radio timepiece 1 to which the present invention is applied will be described. The radio timepiece 1 according to the second embodiment has a configuration in which the reception control unit 60 of the first embodiment shown in FIG. 1 is replaced with a reception control unit 60c.

  FIG. 10 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62 according to the second embodiment. The reception control unit 60c in the second embodiment has a configuration in which a noise elimination circuit 629 is provided between the detection circuit 626 and the third filter circuit 627 in the first embodiment illustrated in FIG. Further, the edge pulse signal b output from the noise timing signal generation unit 86 is output to the noise deletion circuit 629. In addition, the same code | symbol is attached | subjected to the component same as the electromagnetic wave receiver 62 shown and demonstrated in FIG. 2 in Embodiment 1, and the description is abbreviate | omitted.

  Similar to the first embodiment, the display control signal generation unit 80 outputs the display control signal a to the noise timing signal generation unit 86. The antenna ANT receives the reception signal e. A noise signal c is mixed and superimposed on the received signal e, and the antenna ANT converts the received signal e into an electric signal and outputs it to the RF amplifier circuit 620. The RF amplifier circuit 620 amplifies the input received signal e with an amplification degree corresponding to the RF control signal k 1 and outputs the amplified signal to the first filter circuit 621.

  The IF amplifier circuit 625 amplifies the signal input by the second filter circuit 624 with an amplification degree corresponding to the IF control signal k2, and outputs the amplified signal to the detection circuit 626 as an intermediate frequency signal if1.

  The detection circuit 626 detects the input intermediate frequency signal if1 and outputs a detection signal i. Specifically, the baseband signal (the outer edge l of the received signal e (intermediate frequency signal if1) shown in FIG. 6B) that is an amplitude component is detected from the intermediate frequency signal if1. Further, the positive component of the amplitude component of the intermediate frequency signal if1 (above the center line L2), the negative component (below the center line L2), or the sum of the absolute values of the positive component and the negative component is detected signal i (FIG. 12) to the noise elimination circuit 629.

  The noise removal circuit 629 outputs the detection signal i input from the detection circuit 626 as no signal for a certain period of time in synchronization with the edge pulse signal b input from the noise timing signal generation unit 86. Specific processing of the noise removal circuit 629 will be described using the flowchart of FIG. 11 and the schematic waveform of the signal of FIG.

  First, when the noise deletion circuit 629 detects the edge pulse signal b (FIG. 6C) input from the noise timing signal generation unit 86 (step S21: Yes), the edge pulse signal is synchronized with the edge pulse signal b. During the ON time of b, that is, the time corresponding to the pulse width Pw, the detection signal i is set to no signal (step S23). Specifically, the signal between time t1 and time t2 and between time t3 and time t4 shown in FIG. Then, a signal including a non-signal portion of the detection signal i is output to the third filter circuit 627 as a detection signal g (FIG. 7A) (step S25).

  If the edge pulse signal b is not detected in step S21 (step S21: No), the detection signal g is output as it is to the third filter circuit 627 (step S25).

  The third filter circuit 627 performs a process of smoothing the input detection signal g in the same manner as in the first embodiment, and outputs it to the time code conversion unit 70 as the time correction signal h (FIG. 7B).

  As described above, according to the second embodiment, the noise deletion circuit 629 receives the edge pulse signal b, and outputs the detection signal i as no signal in synchronization with the edge pulse signal b. Therefore, even if the noise signal c generated around the display device 88 and the display device 88 is mixed from the antenna ANT, the standard radio wave d of the portion where the noise signal c is mixed is set to the no-signal state by the noise deletion circuit 629. And the same effects as those of the first embodiment can be obtained.

  In the second embodiment, the noise removal circuit 629 is provided between the detection circuit 626 and the third filter circuit 627. However, the present invention is not limited to this, and can be changed as appropriate. Hereinafter, a third modification in which the noise removal circuit 629 is replaced with the noise removal circuit 629a and further provided between the IF amplification circuit 625 and the detection circuit 626 will be described.

(Modification 3)
FIG. 13 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62 in the third modification. The reception control unit 60d in Modification 3 has a configuration in which the noise deletion circuit 629 in FIG. 10 is replaced with a noise deletion circuit 629a, and the noise deletion circuit 629a is further provided between the IF amplification circuit 625 and the detection circuit 626. In addition, the noise timing signal generation unit 86 outputs the edge pulse signal b to the noise deletion circuit 629a. In addition, the same code | symbol is attached | subjected to the component same as the electromagnetic wave receiver 62 shown and demonstrated in FIG. 10 in Embodiment 2, and the description is abbreviate | omitted.

  According to FIG. 13, output signals from the IF amplification circuit 625 and the noise timing signal generation unit 86 are input to the noise deletion circuit 629a which is a feature of the third modification. Further, the intermittent signal f that is an output signal of the noise elimination circuit 629a is output to the detection circuit 626.

  Specifically, when the noise elimination circuit 629a detects the edge pulse signal b output from the noise timing signal generation unit 86, the noise elimination circuit 629a corresponds to the ON time of the edge pulse signal b, that is, the pulse width Pw in synchronization with the edge pulse signal b. During this period, the intermediate frequency signal if1 is set to no signal. The intermediate signal including the non-signal portion of the intermediate frequency signal if1 is output to the detection circuit 626 as an intermittent signal f. The detection circuit 626 detects the input intermittent signal f and outputs the detection signal g to the third filter circuit 627 and the AGC circuit 628.

  As described above, according to the third modification, the intermediate frequency signal if1 is output to the noise elimination circuit 629a as no signal during the time synchronized with the pulse width Pw of the edge pulse signal b. Further, the output signal (intermittent signal f) is detected by a detection circuit 626 and output as a detection signal g. Therefore, even if the noise signal c generated around the display device 88 and the display device 88 is mixed from the antenna ANT, the received signal e of the portion where the noise signal c is mixed is set to the no-signal state by the noise deletion circuit 629a. Therefore, the same effect as in the second embodiment can be obtained.

[Embodiment 3]
Next, a third embodiment of the radio timepiece 1 to which the present invention is applied will be described. The radio timepiece 1 in the third embodiment has a configuration in which the radio wave receiver 62 of the first embodiment shown in FIG. 2 is replaced with a radio wave receiver 62e.

  FIG. 14 is a block diagram illustrating an example of a circuit configuration of the radio wave receiver 62e according to the third embodiment. The radio wave receiving device 62e according to the third embodiment includes an antenna unit 640, an amplifier 642, a detection unit 644, a low-pass filter 646, a short circuit 648, a noise timing signal generation unit 86, and a display device 88. The In addition, the same code | symbol is attached | subjected to the component same as the electromagnetic wave receiver 62 shown and demonstrated in FIG. 2 in Embodiment 1, and the description is abbreviate | omitted.

  The antenna unit 640 is a resonance circuit configured by connecting a coil 640a and a capacitor 640b in parallel. The antenna unit 640 receives the standard radio wave d, converts the received radio wave into an electrical signal (reception signal p), and outputs the electrical signal.

  The short circuit 648 includes a field-effect transistor (FET) 648a, and shorts the output of the antenna unit 640 based on the smoothed pulse signal r output from the low-pass filter 646. Specifically, the output of the antenna unit 640 is short-circuited while the smoothing pulse signal r is applied as the gate voltage of the FET 648a. A signal including a no-signal state due to a short circuit of the short circuit 648 is defined as an intermittent signal q.

  The amplifier 642 amplifies (or attenuates) the intermittent signal q with an amplification degree corresponding to the gain control signal k5 output from the detection unit 644 and outputs the amplified signal to the detection unit 644. The amplifier 642 corresponds to the RF amplifier circuit 620 of the first embodiment.

  The detection unit 644 detects the intermittent signal q amplified (or attenuated) by the amplifier 642, extracts a standard time code, and outputs the standard time code to the CPU 10. Further, based on the signal level of the detected signal, a gain control signal k5 is generated and output to the amplifier 642. The detection unit 644 includes, for example, the RF amplification circuit 620, the first filter circuit 621, the frequency conversion circuit 622, the local oscillation circuit 623, the second filter circuit 624, the IF amplification circuit 625, the detection circuit 626, and the first embodiment. The third filter circuit 627, the AGC circuit 628, and the time code conversion unit 70 are provided.

  The low-pass filter 646 includes a resistor 646a and a capacitor 646b, smoothes the edge pulse signal b output from the noise timing signal generation unit 86, and outputs the smoothed pulse signal r to the short circuit 648.

  Next, a specific operation of the radio wave receiver 62e will be described with reference to FIG. FIG. 6A is a schematic waveform of the display control signal a output from the display device 88. A noise signal c (FIG. 4C) is generated from the display device 88 and the periphery of the display device 88 so as to be synchronized with the edge portion of the display control signal a, and is mixed into the standard radio wave d.

  FIG. 15B is a schematic diagram of the waveform of the received signal p received by the antenna unit 640. A noise signal c is mixed and superimposed on the received signal p.

  The noise timing signal generator 86 generates an edge pulse signal b (FIG. 15C) synchronized with the edge portion of the display control signal a, and the low-pass filter 648 smoothes the edge pulse signal b (FIG. 15). The smoothed pulse signal r as shown in (d) is output.

  The short circuit 648 shorts the output of the antenna unit 640 while the smoothing pulse signal r is input, for example, between times t10 and t12. As a result, as shown in FIG. 15E, the intermittent signal q including the signal in the no-signal state in the received signal p between the times t10 to t12 and the times t14 to t16 is output to the amplifier 642. Further, in FIG. 15B, the influence of the noise c remains on the received signal for a while, but in FIG. 15E, the influence of the noise c does not remain on the received signal.

  As described above, according to the third embodiment, the edge pulse signal b output from the noise timing signal generation unit 86 is smoothed by the low-pass filter 646 and input to the short circuit 648. Then, the short circuit 648 shorts the output of the antenna unit 640 while the smoothing pulse signal r is being applied. Thereby, the energy accumulated in the antenna unit 640 is dissipated, and the noise signal c can be prevented from propagating to the subsequent circuit, and the same effect as in the first embodiment can be obtained.

  Further, since the edge pulse signal b is a pulse waveform signal similar to the display control signal a, noise may be generated in synchronization with the edge portion of the edge pulse signal b. By smoothing the edge pulse signal b in the low-pass filter 646, noise generated by the edge pulse signal b is reduced. As a result, it is possible to prevent deterioration of reception due to noise generated due to the influence of the edge pulse signal b.

[Embodiment 4]
Next, Embodiment 4 will be described with reference to FIG.
In Embodiments 1 to 3 described above, the case where the present invention is applied to a radio timepiece has been described. In the present embodiment, a case where the present invention is applied to a repeater will be described. A repeater is a device that is installed near the window of a building such as a steel house where radio waves are difficult to reach inside, receives long wave standard radio waves, obtains accurate time information, and transmits this time information. The radio timepiece installed indoors receives time information transmitted from the repeater and corrects the time.

  FIG. 16 is a block diagram showing an example of a circuit configuration of the repeater 2 to which the present invention is applied. Note that the configuration of the repeater 2 is the same as that of the radio timepiece 1 of FIG. Therefore, in the following, the same elements as those in FIG.

  The transmission unit 100 transmits the standard time code input from the CPU 10 as a relay radio wave via an antenna or the like using a predetermined carrier wave. The carrier wave at this time may be the same as the received long wave standard radio wave, or may be a dedicated radio wave as a relay radio wave. When it is the same as the long wave standard radio wave, the radio wave clock installed in the room or the like may be a normal radio wave clock. In addition, when a dedicated radio wave is used as a relay radio wave, the radio-controlled timepiece needs a means for receiving the radio wave.

  As described above, according to the fourth embodiment, the repeater 2 includes the radio timepiece 1 shown in the first and second embodiments as a constituent element. Therefore, it is possible to realize a repeater that can obtain the same effects as those of the first and second embodiments. Further, by replacing the radio wave receiving device 62 of the repeater 2 with the radio wave receiving device 62e of FIG. 14 in the third embodiment, a repeater that can obtain the same effect as that of the third embodiment can be realized.

  As described above, according to the four embodiments, the operation of each circuit unit constituting the radio timepiece 1 is stopped for a certain time by the edge pulse signal b generated based on the display control signal a output from the display control signal generation unit 80. Or control the signal level of the output signal. Thereby, the signal of the part in which the noise signal c of the reception signals e and p is mixed is not propagated to the subsequent circuit. Therefore, it is possible to prevent the influence of noise generated inside the main body.

  In the above four embodiments, the edge pulse signal b is generated from the edge portion of the liquid crystal drive signal (display control signal a) synchronized with the segment signal output from the display control signal generation unit. However, the present invention is applicable. This is not limited to this, and can be changed as appropriate. For example, the edge pulse signal b may be generated based on a control signal such as a common signal for controlling the LCD. Thereby, the influence by the noise emitted from a common signal can be prevented.

  Further, the control pulse that is the basis of the edge pulse signal b is the display control signal a, but the present invention is not limited to this and can be changed as appropriate. For example, the edge pulse signal b may be generated based on an operation signal based on ON / OFF of the backlight of the display device 88, or the edge pulse may be generated based on control signals for various circuits and functions incorporated in the radio timepiece. Of course, it is possible to generate the signal b.

  Further, although the superheterodyne method is used as the reception method of the reception control unit 60, a straight method may be used. FIG. 17 is a diagram illustrating a circuit configuration of the straight-type reception control unit 61. As shown in the figure, the reception control unit 61 includes a reception antenna ANT, an RF amplification circuit 620, a filter circuit 630, and a detection circuit 632. In order to apply the straight-type reception control unit 61 to each of the above-described embodiments, each configuration may be changed as follows.

  In order to apply to the first embodiment, the edge pulse signal b of the noise timing signal generator 86 is output to the RF amplifier circuit 620, and the output operation of the RF amplifier circuit 620 is switched by the edge pulse signal b. Further, a third filter circuit 627 that smoothes the detection signal output from the detection circuit 632 and outputs it to the time code conversion unit 70 may be provided.

  In order to apply to the first modification, a switch circuit SW that dissipates the energy of the reception signal output from the antenna ANT based on the edge pulse signal b is provided. Further, a third filter circuit 627 that smoothes the detection signal output from the detection circuit 632 and outputs it to the time code conversion unit 70 may be provided.

  In order to apply to the second modification, an AGC circuit 628b that outputs an RF control signal for controlling the amplification degree of the RF amplifier circuit 620 based on the detection signal output from the detection circuit 632 and the edge pulse signal b is provided. Further, a third filter circuit 627 that smoothes the detection signal output from the detection circuit 632 and outputs it to the time code conversion unit 70 may be provided.

  In order to apply to the second embodiment, a noise deletion circuit 629 that temporarily stops the output of the detection signal output from the detection circuit 632 to the time code conversion unit 70 is provided based on the edge pulse signal b. Further, a third filter circuit 627 that smoothes the signal output from the noise removal circuit 629 and outputs the signal to the time code conversion unit 70 may be provided.

  In order to apply to the third modification, a noise elimination circuit 629a is provided in which the filter circuit 630 temporarily stops outputting the signal to the detection circuit 632 based on the edge pulse signal b. Further, a third filter circuit 627 that smoothes the detection signal output from the detection circuit 632 and outputs it to the time code conversion unit 70 may be provided.

  In order to apply to the third embodiment, a short circuit 638 that short-circuits the output of the antenna unit 640 is provided based on the edge pulse signal b, and the low-pass filter that smoothes the edge pulse signal b and outputs it to the short circuit 648. 648 may be provided.

The block diagram which shows the function structure of a radio timepiece. FIG. 2 is a block diagram illustrating a circuit configuration of the radio wave receiving apparatus according to the first embodiment. The flowchart which shows the processing operation of a noise timing signal generation part. The figure which shows the schematic waveform of (a) display control signal, (b) edge pulse signal, (c) noise signal. The flowchart which shows the processing operation of RF amplification circuit. The figure which shows the schematic waveform of (a) standard radio wave, (b) received signal, (c) edge pulse signal, and (d) intermittent signal. The figure which shows the schematic waveform of (a) detection signal and (b) detection correction signal. The block diagram which shows the circuit structure of the electromagnetic wave receiver of the modification 1. FIG. The block diagram which shows the circuit structure of the electromagnetic wave receiver of the modification 2. FIG. 3 is a block diagram illustrating a circuit configuration of a radio wave receiver according to a second embodiment. The flowchart which shows the processing operation of a noise removal circuit. FIG. 6 is a diagram illustrating a schematic waveform of a detection signal according to the second embodiment. The block diagram which shows the circuit structure of the electromagnetic wave receiver of the modification 3. FIG. 4 is a block diagram illustrating a circuit configuration of a radio wave receiver according to a third embodiment. The figure which shows the schematic waveform of (a) display control signal, (b) reception signal, (c) edge pulse signal, (d) smoothing pulse signal, and (e) intermittent signal. The block diagram which shows the function structure of a repeater. The block diagram which shows the circuit structure of the reception control part of a straight system. The figure which shows the waveform of a long wave standard radio wave.

Explanation of symbols

80 Display Control Signal Generation Unit 82 Delay Circuit Unit 86 Noise Timing Signal Generation Unit 88 Display Device ANT Antenna 620 RF Amplification Circuit 625 IF Amplification Circuit 626 Detection Circuit 627 Third Filter Circuit 628 AGC Circuit 629 Noise Deletion Circuit

Claims (8)

In a radio wave receiving apparatus including a receiving unit that receives a reception signal with an antenna and a display unit that displays information,
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal and converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal ;
A noise timing signal output means for detecting an edge portion of a display control signal of a pulse waveform shape output for display control of the display portion, and outputting a noise timing signal synchronized with the generation timing of the edge portion;
Amplification operation stop control means for controlling to temporarily stop the control operation for amplifying the received signal for a predetermined time in synchronization with the noise timing signal output from the noise timing signal output means When,
Smoothing output means for smoothing and outputting the output detection signal when a signal for which the control operation for amplifying the received signal by the control of the amplification operation stop control means is output as the detection signal; ,
A radio wave receiving apparatus comprising: In a radio wave receiving apparatus including a receiving unit that receives a reception signal with an antenna and a display unit that displays information,
A noise timing signal output means for detecting an edge portion of a display control signal of a pulse waveform shape output for display control of the display portion, and outputting a noise timing signal synchronized with the generation timing of the edge portion;
Noise timing signal smoothing means for smoothing and outputting the noise timing signal;
Based on the signal output by the noise timing signal smoothing means, signal short-circuit control means for short-circuiting the antenna and dissipating the energy of the received signal for a predetermined time;
In synchronization with the noise timing signal output from the noise timing signal output means, a reception signal control means for dissipating the energy of the reception signal by short-circuiting the antenna for a predetermined time;
A radio wave receiving apparatus comprising: In a radio wave receiving apparatus including a receiving unit that receives a reception signal with an antenna and amplifies with a gain according to a gain control signal and a display unit that displays information,
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal and converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal;
A noise timing signal output means for detecting an edge portion of a display control signal of a pulse waveform shape output for display control of the display portion, and outputting a noise timing signal synchronized with the generation timing of the edge portion;
Gain control signal output means for outputting a signal for attenuating gain from the gain control signal for a predetermined time in synchronization with the noise timing signal output from the noise timing signal output means;
Smoothing output means for smoothing and outputting the detection signal output by detecting the intermediate frequency signal when a signal for attenuating gain is output from the gain control signal under the control of the gain control signal output control means; ,
A radio wave receiving apparatus comprising: In a radio wave receiving apparatus including a receiving unit that receives and amplifies a reception signal with an antenna and outputs a detection signal and a display unit that displays information,
A signal obtained by amplifying the received signal is combined with a predetermined oscillation signal and converted into an intermediate frequency signal, and a detection signal output means for outputting a detection signal based on the converted intermediate frequency signal;
A noise timing signal output means for detecting an edge portion of a display control signal of a pulse waveform shape output for display control of the display portion, and outputting a noise timing signal synchronized with the generation timing of the edge portion;
In synchronization with the noise timing signal output from the noise timing signal output means, a signal control means for making the signal output from the detection signal a no signal for a predetermined time, and
Smoothing output means for smoothing and outputting the output detection signal when the signal output from the detection signal is no signal under the control of the signal control means;
A radio wave receiving apparatus comprising: In a radio wave receiving apparatus including a receiving unit that amplifies a received signal received by an antenna, combines a predetermined oscillation signal, converts the signal into an intermediate frequency signal, and outputs it as a detection signal, and a display unit that displays information.
A noise timing signal output means for detecting an edge portion of a display control signal of a pulse waveform shape output for display control of the display portion, and outputting a noise timing signal synchronized with the generation timing of the edge portion;
In synchronization with the noise timing signal output from the noise timing signal output means, a predetermined time, intermediate frequency signal control means for making the intermediate frequency signal no signal, and
Smoothing output means for smoothing and outputting the detection signal output by detecting the intermediate frequency signal when the intermediate frequency signal is set to no signal under the control of the intermediate frequency signal control means in the previous period;
A radio wave receiving apparatus comprising: In the radio wave receiver according to any one of claims 1 to 5 ,
Display control signal generating means for generating a display control signal having a pulse waveform shape for display control of the display unit;
A radio wave receiving apparatus, further comprising time delay control means for delaying display control by the display control signal generated by the display control signal generation means for a predetermined time. The radio wave receiver according to any one of claims 1 to 6 ,
Time code generating means for generating a standard time code based on a standard radio signal included in a signal output from the radio receiver;
Time counting means for counting the current time;
Correction means for correcting current time data counted by the time counting means based on the standard time code generated by the time code generating means;
A radio timepiece characterized by comprising. The radio wave receiver according to any one of claims 1 to 6 ,
Time code generating means for generating a standard time code based on a standard radio signal included in a signal output from the radio receiver;
Transmitting means for transmitting the standard time code generated by the time code generating means;
A repeater characterized by comprising: