JPH087933B2 - Control signal generation circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of use] The present invention relates to a control signal generation circuit suitable for application to, for example, a VTR audio reproduction device.

[Outline of Invention]

The present invention relates to a control signal generation circuit suitable for application to, for example, a VTR audio reproduction device, which is turned on / off according to the presence or absence of a detection signal of a predetermined level, and has a first end connected to one power supply terminal. One end of the constant current source and the other end of the first constant current source are connected in series and the other end is connected to the other power supply terminal, and the same current as the ON current of the first constant current source flows. As described above, the second constant current source that is always turned on regardless of whether the first constant current source is on or off, and the second constant current source connected in parallel to the first constant current source, Has a third constant current source that is constantly turned on with a small current, is connected in parallel to the second constant current source, and is charged and discharged according to the on / off state of the first constant current source, A capacitor that determines the time from the rise of the detection signal to the rise of the control signal. And a charging voltage of the capacitor charged according to the ON operation of the first constant current source is compared with a reference voltage, and a control signal is generated based on the comparison result. The capacity of the circuit element can be reduced and the operation function of the main body of the circuit element can be exhibited.

[Conventional technology]

Conventionally, in a VTR audio reproducing apparatus, a control signal generating circuit for controlling to mute when dropout occurs has a configuration as shown in FIG.

In FIG. 2, (1) is an input terminal to which the envelope signal of the RF signal reproduced by the magnetic head is supplied, and this input terminal (1) is connected to the NPN transistor (2).
, The collector of this transistor (2) is connected to the power supply terminal (3) to which DC power is supplied, the emitter of this transistor (2) is connected to the emitter of the NPN transistor (4), and The connection point is grounded through the constant current circuit (5).

The collector of this transistor (4) is connected to the collector of a diode-connected PNP type transistor (6), and the base of this transistor (4) is grounded through a reference voltage source (8).

The emitter of the transistor (6) is connected to the power supply terminal (3) via the resistor (7). In this case, the transistors (2), (4), (6), the constant current circuit (5), and the reference voltage source (8) constitute a dropout detection circuit, and the envelope signal supplied to the input terminal (1) is first 3 There is a dropout as shown in FIG. A, ie transistor (2)
When the envelope signal supplied to the base of the transistor becomes a voltage lower than the reference voltage from the reference voltage source (8) supplied to the base of the transistor (4), the transistor (4) is turned on and the power supply terminal ( The current ( _denoted as I ₀ ) from 3) flows through the transistor (6) which constitutes a diode.

The base of this transistor (6) is connected to the base of a PNP type transistor (10) that forms a current mirror circuit together with this transistor (6), and the emitter of this transistor (10) is connected to a power supply via a resistor (9). Connected to the terminal (3), the collector of this transistor (10) is grounded through the resistor (11). The collector of the transistor (10) is connected to the base of the NPN type transistor (13), and the base of the transistor (13) is grounded via the capacitor (12). Therefore, the power supply terminal (3)
When the current I ₀ from the current flows to the transistor (6), the constant current I ₀ also flows to the transistor (10),
This charges the capacitor (12).

Further, when no current flows through the transistor (6), the transistor (10) is turned off, and at this time, the electric charge charged in the capacitor (12) is discharged through the resistor (11).

The collector of the transistor (13) is connected to the power supply terminal (3).
The emitter of this transistor (13) is connected to the emitter of the NPN type transistor (14), and the connection point between the emitter of this transistor (13) and the emitter of the transistor (14) is connected via the constant current circuit (15). Grounded, the collector of this transistor (14) is a diode-connected PNP
The transistor (16) is connected to the collector, and the base of the transistor (14) is grounded through the reference voltage source (18).

The emitter of the transistor (16) is connected to the power supply terminal (3) via the resistor (17). In this case, the charging voltage of the capacitor (12) is the reference voltage source (18) as shown in FIG.
When the voltage is higher than the reference voltage of, the transistor (14) is turned off and the current from the power supply terminal (3) is
It stops flowing to 6).

The charging voltage of the capacitor (12) is supplied to the base of the transistor (14) by the capacity of the capacitor (12), the resistance value of the resistor (11), and the current value of the current flowing through the transistor (10). The time (eg, 150 μsec) for exceeding the voltage of the reference voltage source (18) is determined. Further, this time is the time when the control signal supplied to the transistor (13) rises after the transistor (6) rises.

The base of the transistor (16) is connected to this transistor (1
Connected to the base of a PNP transistor (19) that forms a current mirror circuit together with 6), and this transistor (19)
The emitter of is connected to the power supply terminal (3) through the resistor (20), and the collector of this transistor (19) is connected to the mute pulse generating circuit (21) for generating the mute pulse as shown in FIG. This mute pulse generation circuit (21)
The output side of is connected to the base of the mute NPN transistor (22).

Therefore, when the transistor (16) is turned off and the current from the power supply terminal (3) stops flowing through this transistor (16), no current flows through the transistor (19), either.
This state is detected by the mute pulse generating circuit (21), and the mute pulse from the mute pulse generating circuit (21) is supplied to the base of the transistor (22).

Reference numeral (23) is an input terminal to which an audio signal is supplied. The audio signal supplied to the input terminal (23) is converted into a resistor (24), a resistor (25), a terminal (26) and an audio amplifier circuit (27). ) To the speaker (28) so that it can be monitored.

In addition, the collector of the transistor (22) is connected to the resistor (24).
And this transistor (22) connected to the connection point of (25)
Ground the emitter of. Therefore, the mute pulse is generated from the mute pulse generation circuit (21) by this transistor (22).
Audio signal input terminal (2
The audio signal from 3) is grounded.

RF supplied to the input terminal (1) in the above circuit
When a dropout occurs in the envelope signal of the signal and the dropout falls below the voltage value of the reference voltage source (8), that is, the threshold level, the transistor (4) is turned on, and the current (I ₀ ) flows through the transistor (6). There current flows I ₀ flows through the transistor (10) constituting a current mirror circuit together with the transistor (6), the current I ₀ flows in the capacitor (12), a capacitor (12) is charged, the capacitor (12 ) Is the voltage value of the reference voltage source (18),
That is, when the threshold level is exceeded, the transistor (14) is turned off, and current does not flow through the transistor (16). As a result, current does not flow through the transistor (19), and this state is transferred to the mute pulse generation circuit (21). To be detected. Then, a mute pulse is generated from the mute pulse generation circuit (21), and this is supplied to the base of the transistor (22) to input the audio signal input terminal (23).
The audio signal supplied to the
No sound is emitted from 8).

When the dropout disappears, the current I ₀ due to the charge stored in the capacitor (12) flows to the ground side through the resistor (11).

[Problems to be Solved by the Invention]

By the way, in the control signal generating circuit described above, normally, the capacitor (12) is used for reasons such as reducing the circuit scale.
It is considered to reduce the capacity of the. To reduce the capacity of the capacitor (12), the transistor (6),
The current flowing in (10) should be reduced. However, if the current flowing through the transistors (6), (10) is reduced, the transistors (6), (10), (4), (1
Since 3), (14), (16), (19), and (22) cannot perform the original operation function, this circuit does not perform the original mute operation. Therefore, a capacitor having a large capacity is generally used.

However, if the capacity of the capacitor (12) is large,
Since the discharge time of this capacitor (12) becomes long, the audio signal from the input terminal (23) remains muted even if the dropout disappears.

The present invention has been made in view of the above points, and is capable of reducing the capacity of a capacitor to be used and exhibiting the original operation function of a circuit element.

[Means for solving the problem]

According to the present invention, a first constant current source whose one end is connected to one power supply terminal and which is turned on / off according to the presence or absence of a detection signal of a predetermined level, and one end of which is provided at the other end of the first constant current source. Connected in series and the other end connected to the other power supply terminal,
A second constant current source that is always turned on regardless of whether the first constant current source is on or off so that the same current as the on-current of the first constant current source flows, and the first constant current source. A third constant current source which is connected in parallel and which is always turned on with a current smaller than the current of the first constant current source;
And a capacitor that is connected in parallel to the constant current source and is charged / discharged in accordance with ON / OFF of the first constant current source, and that determines the time from the rise of the detection signal to the rise of the control signal; The charging voltage of the capacitor charged according to the ON operation of the constant current source is compared with the reference voltage, and a control signal is generated based on the result.

[Action]

According to the invention described above, when no dropout is detected, the current from the transistor (40) is Power to the transistor (31) and when dropout is detected, the power from the transistor (10)
The current from the transistor (40), with I ₀ flowing in the transistor (31) Flows into the capacitor (12) and charges the capacitor (12), so that the capacity of the capacitor (12) can be reduced and the original operation function of the circuit element can be exhibited.

〔Example〕

An example in which the control signal generating circuit of the present invention is applied to a mute signal generating circuit for controlling to mute when dropout occurs in a VTR audio reproducing apparatus will be described in detail below with reference to FIG. To do. In FIG. 1, parts corresponding to those in FIG. 2 are designated by the same reference numerals, and duplicate description thereof will be omitted.

In FIG. 1, the input terminal (1) to which the envelope signal of the reproduced RF signal is supplied is connected to the base of the NPN transistor (2), and the collector of this transistor (2) is connected to the DC power source. Connect to the power supply terminal (3) to be supplied, and connect the emitter of this transistor (2)
It is connected to the emitter of the NPN type transistor (4), and the connection point between the emitter of this transistor (2) and the emitter of the transistor (4) is connected to the collector of the NPN type transistor (29) forming the constant current circuit. The emitter of the transistor (29) is grounded via the resistor (30).

The collector of the transistor (4) is connected to the collector of a diode-connected PNP type transistor (6), and the base of the transistor (4) is grounded through a reference voltage source (8).

The emitter of the transistor (6) is connected to the power supply terminal (3) via the resistor (7). In this case, the transistors (2), (4), (6), (29) and the reference voltage source (8) constitute a dropout detection circuit, and the envelope signal of the RF signal supplied to the input terminal (1). When a voltage lower than the reference voltage due to the dropout occurs in the transistor (4), the transistor (4) is turned on, and the current I ₀ from the power supply terminal (3) flows through the transistor (6). The base of the transistor (6) that forms the diode is connected to the base of the PNP transistor (10) that forms the current mirror circuit together with this transistor (6), and the emitter of this transistor (10) is connected through the resistor (9). To the power supply terminal (3), and the collector of this transistor (10) is connected to the collector of the NPN type transistor (31). In this case, when the current I ₀ flowing through the transistor (6), the transistors constituting the transistor (6) a current mirror circuit (10) also flows through the current I _0. The emitter of the transistor (31) is grounded via the resistor (32), and the base of the transistor (31) is connected to the base of the transistor (29).

The collector of the diode-connected NPN transistor (33) is connected to the power supply terminal (3) through the resistor (35), and the emitter of this transistor (33) is connected to the resistor (34).
And the base of the transistor (33) is connected to the base of the transistor (31).

Therefore, this transistor (33) and transistor (2
9) forms a current mirror circuit, and the current I ₀ flows through this transistor (33). Therefore, a transistor (29) that forms a constant current circuit with the resistor (30).
Also the constant current I ₀ flows.

Further, the transistor (33) and the transistor (31) form a current mirror circuit, and the constant current I ₀ flows through the transistor (31) that forms the constant current circuit with the resistor (32).

The collector of an NPN transistor (36) is connected to the collector of a diode-connected PNP transistor (39), and the emitter of this transistor (36) is a resistor (37).
The base of the transistor (36) is connected to the base of the diode-connected transistor (33) via the.

The transistor (33) and the transistor (36) form a current mirror circuit, and a constant current I ₀ flows through the transistor (36) that forms a constant current circuit with the resistor (37).

The emitter of the diode-connected transistor (39) is connected to the power supply terminal (3) through the resistor (38), and the base of this transistor (39) is connected to this transistor (39).
And PNP type transistor (4
0), the emitter of this transistor (40) is connected to the power supply terminal (3) through the resistor (41),
The collector of this transistor (40) is connected to the base of the NPN transistor (13).

The transistor (39), the constant current I ₀ to the transistor (36) flows a constant current I ₀ flows in the transistor (39) to the transistor (40) constituting a current mirror circuit transistor (39) The ratio of the emitter area of the transistor (39) to the emitter area of the transistor (40) is determined so that a current 1/10 of the flowing current I ₀ , that is, a current I _0/10 flows.

Further, the connection point between the collector of the transistor (10) and the collector of the transistor (31) is connected to the base of the transistor (13), and the base of the transistor (13) is grounded via the capacitor (12). Therefore, when no dropout is detected, a constant current I ₀ is applied to the transistor (36).
, A constant current I ₀ also flows through the transistor (39),
Transistor a constant current I _0/10 from (40) flows through the transistor (31), when dropout is detected, the current I ₀ flows in the transistor (10), the transistor (40)
Since the constant current I _0/10 from flowing to the capacitor (12) is charged capacitor (12).

The collector of the transistor (13) is connected to the power supply terminal (3).
The emitter of this transistor (13) is connected to the emitter of the NPN type transistor (14), and the connection point between the emitter of this transistor (13) and the emitter of the transistor (14) is connected via the constant current circuit (15). Grounded, the collector of this transistor (14) is a diode-connected PNP
The transistor (16) is connected to the collector, and the base of the transistor (14) is grounded through the reference voltage source (18).

The emitter of the transistor (16) is connected to the power supply terminal (3) via the resistor (17). In this case, the charging voltage of the capacitor (12) is the reference voltage source (18) as shown in FIG.
When the voltage is higher than the reference voltage of, the transistor (14) is turned off and the current from the power supply terminal (3) is
It stops flowing to 6).

Also, depending on the capacity of this capacitor (12) and the current value of the current flowing through the transistor (40), the capacitor (12)
The charging voltage of the transistor exceeds the voltage of the reference voltage source (18) supplied to the base of the transistor (14) (eg 150 μs).
ec). Further, this time is the time when the control signal supplied to the transistor (13) rises after the transistor (6) rises.

The base of the transistor (16) is connected to this transistor (1
Connected to the base of a PNP transistor (19) that forms a current mirror circuit together with 6), and this transistor (19)
Is connected to the power supply terminal (3) through the resistor (20), and the collector of this transistor (19) is connected to the mute pulse generating circuit (21) for generating the mute pulse as shown in FIG. 3C. , This mute pulse generation circuit (2
Connect the output side of 1) to the base of NPN transistor (22) for mute.

Therefore, when the transistor (16) is turned off and the current from the power supply terminal (3) stops flowing through this transistor (16), no current flows through the transistor (19), either.
This state is detected by the mute pulse generating circuit (21), and the mute pulse from the mute pulse generating circuit (21) is supplied to the base of the transistor (22).

Reference numeral (23) is an input terminal to which an audio signal is supplied. The audio signal supplied to the input terminal (23) is converted into a resistor (24), a resistor (25), a terminal (26) and an audio amplifier circuit (27). Through the speaker (28) and monitored.

In addition, the collector of the transistor (22) is connected to the resistor (24).
And this transistor (22) connected to the connection point of (25)
Ground the emitter of. Therefore, the mute pulse is generated from the mute pulse generation circuit (21) by this transistor (22).
Audio signal input terminal (2
The audio signal from 3) is grounded.

RF supplied to the input terminal (1) in the above circuit
When a dropout occurs in the envelope signal of the signal, and this drops below the voltage value of the reference voltage (8), that is, the threshold level, the transistor (4) is turned on, and the current I ₀ is supplied to the transistor (6). The current I ₀ also flows through the transistor (10) that forms a current mirror circuit together with the transistor (6).
When the current I _0/10 from the capacitor flows into the capacitor (12), the capacitor (12) is charged, and the voltage of this capacitor (12) exceeds the voltage value of the reference voltage source (18), that is, the threshold level, the transistor (14) is turned off and no current flows through the transistor (16), which causes
No current flows through the transistor (19), and this state is detected by the mute pulse generating circuit (21). And
A mute pulse is generated from the mute pulse generation circuit (21), and the mute pulse is supplied to the base of the transistor (22) and the audio signal supplied to the audio signal input terminal (23) is flowed to the ground side, and is output from the speaker (28). No sound is emitted.

Further, when no drop-out, because the charging current I _0/10 of the capacitor (12), the discharge current is 9 · I ₀ /
Will be 10.

The present invention is not limited to the above-mentioned embodiments, and it goes without saying that various other configurations can be adopted without departing from the gist of the present invention.

〔The invention's effect〕

According to the invention described above, for example, when no dropout is detected, the current from the transistor is Current to the transistor, and when dropout is detected, the current I ₀ from the transistor is allowed to flow to the transistor and the current from the transistor Flows into the capacitor and charges the capacitor, so that the capacity of the capacitor can be reduced to, for example, 1/10, and the original operation function of the circuit element can be exhibited.

Moreover, since the capacitance of the capacitor is small, the mute operation can be released quickly after the dropout is eliminated.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention, FIG. 2 is a circuit diagram showing a conventional example, and FIG. 3 is a waveform diagram. (9), (32), (41) are resistors, (10), (31),
(40) is a transistor and (12) is a capacitor.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Katsumi Imai 2-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Nobuyuki Otaka 2-18th Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd.

Claims (1)

[Claims] 1. A first constant current source whose one end is connected to one power supply terminal and which is turned on and off depending on the presence or absence of a detection signal of a predetermined level, and one end of which is provided at the other end of the first constant current source. Is connected in series and the other end is connected to the other power supply terminal, and is always turned on regardless of whether the first constant current source is on or off so that the same current as the on current of the first constant current source flows. A second constant current source that is connected to the first constant current source in parallel, and is constantly turned on with a current smaller than the current of the first constant current source.
And a constant current source of the first constant current source of the first constant current source of FIG.
And a capacitor that is charged and discharged according to ON / OFF of the constant current source and determines the time from the rise of the detection signal to the rise of the control signal, and the capacitor charged according to the ON operation of the first constant current source. The control signal generating circuit is characterized in that the charging voltage and the reference voltage are compared and a control signal is generated based on the result.