KR900008163B1 - Auto scanning stop circuit of a scanning device - Google Patents

Abstract

A circuit includes a phase sync. loop circuit for controlling the oscillation freq. of a voltage control oscillator (14), a freq. converter (2) for generating an intermediate freq. by mixing the received HF signal and the local oscillation signal, a system controller (23) for selecting a channel, an AGC circuit (20) for controlling gain of an IF amplifier (4), a counter (21), a detecter (22), and a transistor (Q1) for changing the time constant of the AGC circuit to securely select a channel.

Description

Automatic stop circuit of postmarking station

1 is a circuit diagram showing an embodiment of the present invention.

2 is a characteristic diagram for explaining the operating state of the circuit according to the present invention.

Figure 3 (a) (b) is a circuit diagram showing a specific configuration example of the time constant switching circuit according to the present invention.

4 and 5 are circuit diagrams showing a conventional automatic tuning apparatus, respectively.

* Explanation of symbols for main parts of the drawings

1: Input terminal 2: Frequency converter

3: filter 4: intermediate frequency amplifier

5: Detector 6: Output terminal

10: divider 11: phase comparator

12: reference oscillator 13: low pass filter

14: voltage controlled oscillator 15: buffer amplifier

7, 20: automatic gain control circuit 21: counter

22: detection circuit 9, 23: system controller

The present invention relates to an automatic stop circuit of a sweeping tuner used in a receiver. In particular, the automatic stop of a sweeping tuner in which an incorrect sweeping stop does not occur according to the modulation state of a broadcast wave during the sweeping tuner operation. It is about a circuit.

As a superheterodyne type AM receiver which is tuned by sweeping a conventional frequency, such a system as shown in FIGS. 4 and 5 can be exemplified, and the system of FIG. 4 operates as follows.

The high frequency input signal is inputted from the antenna through the input terminal 1 and mixed with the tuned oscillation signal transmitted from the voltage controlled oscillator 14 in the frequency converter 2, wherein the high frequency input signal is tuned to the received high frequency input signal. When the oscillation frequency has a predetermined intermediate frequency relation and a predetermined intermediate frequency signal is obtained from the frequency converter 2, the intermediate frequency signal passes through the filter 3 to the IF input terminal 4a of the intermediate frequency amplifier 4. The signal supplied and amplified by the intermediate frequency amplifier 4 is supplied to the AM detector 5, and the detection output of the AM detector 5 is introduced into the output terminal 6.

On the other hand, in order to obtain the detection output at a normal constant level, the detection output is introduced into the automatic gain control circuit (AGC) 7 and detected at a constant level, and then this level detection output is the gain control terminal of the intermediate frequency amplifier 4. The intermediate frequency amplifier 4 has a predetermined width band characteristic of ± 3 KHz around a predetermined intermediate frequency, for example, 450 KHz.

Subsequently, the output signal of the intermediate frequency amplifier 4 is introduced into the counter 8 that counts the frequency. The counter 8 indicates whether or not the system is tuned while the system is performing the final frequency sweep. It is used as a detection circuit for detecting. On the other hand, when the tuning state is approached, the output signal level of the intermediate frequency amplifier 4 increases, so that the counter 8 counts the signal frequency. When the count value reaches a predetermined value, that is, 450 KHz, which is a predetermined intermediate frequency, the system controller ( 9) detects the count value, and if the count in the counter 8 is made four times every predetermined number of times, for example, every few msecs, the controller 9 stops the frequency sweep operation and maintains the tuning data at the stop. I'm doing it.

In order to generate the local oscillation frequency signal, a circuit in which the phase tuning level is written is used for the frequency sweep, that is, the output of the voltage control generator 14 is input to the divider 10 so that the system controller 9 can be used. The frequency divider is divided according to the tuning data of, and the frequency divider output is compared with the reference oscillation output generated from the reference oscillator 12 in the phase comparator 11.

Thus, the phase error signal between the two signals obtained by the phase comparator 11 is smoothed in the low pass filter 13 and supplied to the frequency control stage of the voltage controlled oscillator 14 as a control signal, thereby The oscillation frequency is controlled so that the reference oscillation frequency generated from the reference oscillator 12 and the divided output signal have a predetermined relationship. At this time, when the oscillation frequency of the voltage controlled oscillator 14, that is, the local oscillation frequency signal is variable, the frequency division ratio of the frequency divider 10 may be changed by the system controller 9.

On the other hand, in the case of pre-selection tuning, the system controller 9 starts frequency sweeping in response to key input from a keyboard, for example, and when there is a broadcast high frequency signal on the way, the intermediate frequency amplifier 4 As the output signal coefficient becomes a predetermined value, the system controller 9 stops the frequency sweep.

The receiving system of FIG. 5 is also an automatic receiving apparatus using a phase locked loop. Therefore, the same functional parts as the circuit of FIG. 4 are shown with the same reference numerals as in FIG. However, in the receiving system of FIG. 5, the means for detecting the tuning condition is different from that of the circuit of FIG. 4. That is, a detection output from the detector 5 is input to the system controller 9 via the buffer amplifier 15. In this case, since the detection output level is increased when the data is tuned, the output is obtained from the buffer amplifier 15, which is used as a sweep operation stop signal.

On the other hand, the frequency stamp indicates that the frequency of the local oscillation frequency signal is changed to 9 KHz (hereinafter referred to as 1 step) as the division ratio of the frequency divider 10 is sequentially changed from the controller 9 by +1 or -1 by the tuning data. Will be converted.

In the conventional automatic tuning apparatus as described above, frequency tuning is performed by varying the tuning frequency by, for example, 9 KHz, but the frequency is adjusted according to the selectivity characteristics of the intermediate frequency amplifier or the broadcast signal modulation and electric field intensity introduced during the frequency sweep operation. A sufficient level of output may be detected from the intermediate frequency amplifier one step before tuning and the sweep operation may be stopped. In other words, if the frequency is in the up search, the frequency can be stopped by one step below the broadcasting signal frequency, and in the case of the down search by the lower frequency, the sweep can be stopped at the frequency up one step. do.

For example, in an area where the broadcast signal can be tuned in 9KHz steps, when a signal with modulation frequency = 9KHz and modulation degree = 100% is tuned, the stop sensitivity before one step receives a regular broadcast signal and adds + 6dB to the stop sensitivity again. Result. Therefore, in the environment of twice the electric field strength at the time of obtaining the normal stop sensitivity, there is a problem that the presumptive stop is made by the side wave detection signal before tuning to the normal broadcast signal. do.

Accordingly, the present invention has been invented to solve the above problems, and provides an automatic stop circuit operation stop circuit of a sweeping station operation apparatus which prevents an erroneous sweeping operation according to a modulation state of a broadcast wave during the sweeping station operation. There is this.

The present invention for achieving the above object is to change the response characteristics of the automatic gain control operation for the intermediate frequency amplifier (4) when the automatic pre-station and the normal reception time, that is, the automatic gain at the time of the pre-station The control response time constant is reduced to obtain a tuning detection signal, and after the sweep is stopped and shifted to the normal reception state, a means is provided for switching the time constant to the value at normal operation.

According to the above configuration, the automatic gain control circuit responds quickly to suppress the sideband signal of the broadcast signal when the automatic post-station operation is performed. Therefore, the detection output is lower than in the case where the automatic gain control function is not performed. Therefore, even if the receiving electric field is strong, the sweep is not stopped before 1 step of the normal frequency tuning state, and it can be surely tuned to the normal broadcast frequency so that the sweep can be stopped.

Hereinafter, the present invention will be described with reference to the embodiment drawings.

1 is an embodiment of the present invention, when a high frequency input is input from the antenna to the input terminal 1, the high frequency input is transmitted to the local oscillation signal sent from the voltage control generator 14 in the frequency converter (2). It is mixed so that a predetermined intermediate frequency signal is obtained. At this time, when the local oscillation frequency is in the predetermined frequency relation with respect to the received high frequency input signal, a predetermined intermediate frequency signal is obtained from the frequency converter 2, and the intermediate frequency signal passes through the filter 3 to the intermediate frequency amplifier 4 A signal supplied to the IF input terminal 4a of the AH) and amplified by the intermediate frequency amplifier 4 is supplied to the AM detector 5, and then the detection output is sent to the output terminal 6.

The detection output is sent to an automatic gain control circuit 20 (hereinafter referred to as an AGC circuit) so that the detection output is always at a constant level so that the level is detected, and the level detection output of the intermediate frequency amplifier 4 It is supplied to the gain control terminal 4b. As described above, the intermediate frequency amplifier 4 has a band characteristic having a predetermined width of about 3 KHz about 450 KHz, which is a predetermined intermediate frequency, as described above.

In addition, the output signal of the intermediate frequency amplifier 4 is sent to the counter 21 that counts the frequency. The counter 21 checks whether or not the tuning state is established while the system is tuned, i.e., frequency sweeping. Is a circuit used to detect. In this case, the output signal level of the intermediate frequency amplifier 4 is increased when it is close to the tuned state, so that the counter 21 counts the signal frequency, and when the count value reaches a predetermined value, i.e., 450 KHz, The detection circuit 22 detects it and supplies the detection output to the system controller 23. When the coefficient at the counter 21 is a predetermined number of times, such as four times, every several msec, the system controller 23 determines that a regular broadcast signal is being received and stops the frequency sweep operation. Tuning data is maintained.

In addition, a circuit using an abnormal synchronization loop is used for generating the local oscillation frequency signal, that is, the output of the voltage controlled oscillator 14 is input to the divider 10, where the system controller 23 is used. The frequency divider is divided according to the tuning data of, and the frequency divider output is compared in phase with the mood oscillation output from the reference oscillator 12 in the phase comparator 11.

Subsequently, the phase error signal between the two signals obtained by the phase comparator 11 is smoothed by the low pass filter 13 and supplied to the frequency control stage of the voltage controlled oscillator 14 as a control signal. The oscillation frequency is controlled so that the reference oscillation frequency from the reference frequency signal oscillator 12 and the divided output signal have a constant relationship.

In this case, when the oscillation frequency of the voltage controlled oscillator 14, that is, the local oscillation frequency signal is to be varied, the division ratio of the frequency divider 10 may be changed with the system controller 23.

On the other hand, in the case of pre-selection tuning, for example, the system controller 23 starts frequency sweeping in response to key input from the keyboard. In the meantime, if there is a broadcast high frequency signal, the output signal coefficient value of the intermediate frequency amplifier 4 becomes a predetermined value as described above, and the system controller 23 stops the frequency sweep.

In the present invention, the response characteristic becomes faster when the AGC circuit 20 performs the automatic post-station operation, that is, the switching signal because the time constant of the AGC circuit 20 is smaller than the time constant during the normal receiving operation. Is drawn from the system controller 23 and is set by, for example, turning on the transistor Q1. The system controller 23 outputs a switching signal in order to reduce the time constant of the AGC circuit 20 when a key input for a pre-selection station is input from a keyboard or a mode controller. Subsequently, when the pre-tuning operation is performed to tune to the frequency of the broadcast signal, an intermediate frequency signal of a predetermined level or more is obtained from the intermediate frequency amplifier 4, and the counter is counted at the counter 21. The count is repeated every msec. The detection circuit 22 detects the presence or absence of the counting operation. At this time, if the counting operation at the counter 21 is performed a predetermined number of times, for example, four times in succession, it is determined that the system controller 23 synchronizes with the regular broadcast signal, and the controller 23 accordingly causes the AGC circuit 20 to perform the counting operation. The time constant of is set to the value in the normal reception state. Subsequently, when there is a key input for tuning, the system controller 23 prohibits the reception of the signal from the detection circuit 22 for a predetermined period (for example, one step variable period), and then starts the automatic frequency sweep operation. As described above, the time constant is changed or the stationary station is stopped.

As described above, in the present invention, the time constant value of the AGC circuit 20 is set to be small when the automatic frequency station is tuned, so that the response characteristic becomes faster. The circuit 20 is suppressed, and the upper and lower sideband signals of the broadcast signal are counted by the counter 21, which is less than or equal to the predetermined number of times, so that an erroneous stop in the controller 23 does not occur.

This will be described with reference to FIG. 2. That is, when the automatic frequency sweep is not performed, the input and output characteristics of the receiver are shown by the solid line of FIG. 2, where the gain of the intermediate frequency amplifier 4 is automatically adjusted as the AGC circuit 20 operates when the electric field is 100 dB / m. It is suppressed to be 30dB lower than when the gain control function does not work (dotted line).

Therefore, if the time constant of the AGC circuit 20 changes up to the modulation frequency band when the electric field is 100 dB / m, the modulation intensity is 1/30 when the frequency stamp is close to the upper or lower band. This means that the sideband level will be -30dB (dotted and dashed line).

Therefore, in the present invention, when the automatic frequency sweep, the gain suppression is achieved by reducing the time constant of the AGC circuit 20 to be adjusted according to the modulation frequency. In this case, the signal is 9KHz and 100% modulated signal. When the sweep is stamped, the stop sensitivity at one step in synchronization with the normal frequency becomes +36 dB (36-30 = +6 dB) at normal time, and if the electric field strength is not as strong as about 30 dB compared to the conventional one, the wrong operation will not occur. .

On the other hand, as a means for switching the time constant of the AGC circuit 20 can be realized in various embodiments. As an example, FIG. 3 (a) shows a switching signal from the system controller 23 at the base of the transistor Q1. When the transistor Q1 is turned on, the parallel circuit of the capacitors C1 and C2 acts as a time constant circuit, and when the transistor Q2 is turned off, the circuit of the capacitor C2 is turned off. Only the time constant circuit acts.

FIG. 3 (b) shows the AGC circuit 20 by controlling the switch SW of any one of the capacitors C3 and C4 having different capacitance values according to the switching signal from the system controller 23. FIG. It is assembled.

As described above, the present invention can provide an automatic stop circuit of a tuning device in which an erroneous sweep stop operation does not occur according to the modulation degree (modulation frequency) of the broadcast wave or the electric field strength during the sweep tuning operation.

Claims (1)

The output of the voltage controlled oscillator 14 is divided by the divider 10, and the divided output is outputted in phase comparator 11 to obtain an error output that is compared with the oscillation signal from the mood oscillator 12 in phase. By supplying to the frequency control stage of the voltage-controlled oscillator 14, the oscillation frequency signal of the voltage-controlled oscillator 14 is controlled so that the oscillation frequency of the reference oscillator 12 and the frequency divider output have a constant relationship. In order to set the reception frequency of the reception harmonic signal, a frequency converter (2) which derives an intermediate frequency signal by mixing a phase synchronization loop circuit, the reception high frequency signal and the local oscillation signal from the voltage controlled oscillator (14). Of the system controller 23 and the frequency converter 2 which give preset data to the frequency divider 10 of the phase-locked loop circuit in response to the tune input, and varies the frequency data. The automatic gain which controls the gain of the intermediate frequency amplifier 4 to which the output is supplied, and the intermediate frequency amplifier 4 so that this input signal may become a predetermined level using the output signal of this intermediate frequency amplifier 4 as an input signal. The control circuit 20, the counter 21 for counting the frequency of the output signal from the intermediate frequency amplifier 4, the detection circuit 22 for detecting that the counter 21 is made, and the detection A receiving system comprising stop means such as a system controller 23 for stopping the frequency sweep when the detection signals are continuously obtained from the circuit 22 a predetermined number of times. The response time constant of the control circuit 20 is switched to a smaller value than in normal reception, and when the detection signal is obtained, the sweeping operation is stopped and the automatic gain agent And a switching means such as a transistor (Q1) for switching the time constant of the fish circuit (20) to return to the value upon normal reception.

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