KR900009030Y1 - Copstan motor control circuit - Google Patents

Abstract

No content.

Description

Capstan motor control circuit during variable speed regeneration

1 is a conventional capstan motor control circuit diagram.

Fig. 2a-k or Fig. 1 is a waveform diagram of each part.

3 is a capstan motor control circuit diagram of the present invention.

4A-B or 3D waveform diagrams.

* Explanation of symbols for main parts of the drawings

11, 13: amplifier 12: microprocessor

14-17: monomulti 18-21: time constant circuit

22: capstan motor drive part TR11-TR14: transistor

SW1-SW3l: Slow and Stop, Frame Playback Switch

HS: Head Switching Signal CFG: Speed Detection Circuit

CTL: Control signal PL: Constant speed control signal

F / : Forward / Reverse Control Signal

The present invention provides a video cassette recorder for recording and reproducing video signals on a video tape, wherein the video signals recorded on the video tape are shifted, i.e., slow playback, slow playback, frame playback, and frame playback. The case relates to a capstan motor control circuit for shift reproduction for controlling the driving of a capstan motor for driving a video tape in a case.

In general, a video cassette recorder drives a capstan motor in an intermittent driving manner, that is, plays a video tape while intermittently moving, which is a one-frame playback that moves a video tape by one frame. If the playback of one frame is continuous, slow playback is performed. In the case of stop playback, the intermittent movement is stopped about 2-3 times in consideration of the response speed of the tape odometer and capstan motor. In shifting reproduction by a slow intermittent driving method, the driving of the capstan motor is conventionally controlled by using a control pulse signal reproduced on a video tape.

That is, the conventional capstan motor control circuit has a low speed reproduction signal SL and a stop reproduction signal ST, a 1 frame reproduction signal FR, a 30 Hz head switching signal HS, and an amplifier as shown in FIG. The variable resistor VR1 and the resistor R1 and the capacitors C1 and C2 are connected to the trigger terminals TI1 and TI2 of the shift control unit 1 through which the regeneration control signal CTL is inputted through 1). The stop signal output terminal SP of the shift control unit 2 is connected to the base of the transistor TR1 and its collector is coupled with the drive signal output terminal DS and the constant speed control signal PL through the diode D1. It is connected to the driving terminal DR of the capstan motor driving unit 3, and the reverse driving signal output terminal RV of the shift control unit 2 is the forward / reverse control signal F / through the resistor R2 and the diode D2. ) Is connected to the base of transistor TR2 through resistor R3 and its collector is connected to resistor R4, and is connected to the base of transistor TR2 through diode D3 and its collector is connected to resistor R4. Is connected to the driving terminal DS of the capstan motor driving unit 3 through the diode D3, and the forward / reverse control terminal of the capstan motor driving unit 3 (FD / ) Is a connection point of the resistor R4 and the diode D2.

In the conventional capstan motor control circuit configured as described above, power is applied to the power supply terminal Vcc, and the driving terminal DR and the forward / reverse control terminal FD / of the capstan motor driving unit 3 are applied. ), The high speed constant speed control signal PL and the forward / reverse control signal F / Is applied, and the capstan motor driving unit 3 drives the capstan motor M1 in the constant speed in the forward direction, and presses the low speed regeneration button, as shown in FIG. 2C, to show the high speed low speed regeneration signal SL at time t1. Is input, the shift control unit 2 outputs a high potential to the stop signal output terminal SP and is applied to the base of the transistor TR1 as shown in FIG. The constant speed control signal PL is grounded through the transistor TR1, and a low potential is applied to the driving terminal DR of the capstan motor driving unit 3 to stop the driving of the capstan motor M1.

In this way, the high frequency is output to the stop signal output terminal SP according to the low speed playback signal SL, and the 30 Hz head switching signal HS input as shown in FIG. When converted upward, the shift control unit 2 causes the trigger terminal TI1 to be cut off, so that the power supply of the power supply terminal Vcc is supplied to the capacitor C1 through the variable resistor VR1 as shown in FIG. When the battery is started to be charged together and a predetermined time T1 elapses after the charging of the capacitor C1 starts, the shift control unit 2 outputs a low potential to the stop signal output terminal SP so that the transistor TR1 is turned off. In addition, as shown in FIG. 2G, the high potential higher than the constant speed control signal PL is output to the drive signal output terminal DS, and the high potential is applied to the drive terminal DR through the diode D1. The capstan motor driving unit 3 drives the capstan motor M2 directly, thereby Thereby driving.

In this state, when the control signal CTL is reproduced and input to the shift control unit 2 through the amplifier 1 as shown in FIG. 2H on the video tape, the shift control unit 2 switches the trigger terminal TI2. In the state of interruption, the power of the power supply terminal Vcc starts to be charged to the capacitor C2 as shown in FIG. 2i through the resistor R2, and after a predetermined time, the trigger voltage abnormality of the capacitor C2 When charged, the charged voltage is discharged to the trigger terminal TI2, and the shift control unit 2 outputs a low potential to the reverse driving signal output terminal RV as shown in FIG. 2j, so that the transistor TR2 is turned off. The power supply of the power supply terminal Vcc is applied to the driving terminal DR of the capstan motor driving unit 3 through the resistor R4 and Iodda D5, and is also output to the reverse driving signal output terminal RV. Forward / reverse control signal F / through resistor R2 by ) Flows through the diode D2 to its output terminal RV, and the forward / reverse control terminal FD / of the capstan motor driving unit 3 As shown in FIG. 2k, a low potential is applied, and the cap steel motor driving unit 3 drives the capstan motor M1 driven in the reverse direction, so that the capstan motor M1 stops rapid braking, that is, stops driving. After a predetermined time T2 has elapsed, the shift control unit 2 outputs a high potential to the stop signal output terminal SP as shown in FIG. 2d and reverse drive signal output terminal RV. The transistor TR2 is turned on and the transistor TR2 is turned on, and a low potential is applied to the driving terminal DR. At this time, the capstan motor driving unit 3 stops driving the capstan motor M1 so that playback of one frame is performed. Is done. This operation is repeated when the 30Hz head switching signal HS is converted from the low potential to the high potential and then the voltage charged in the capacitor C1 becomes a predetermined voltage or more and is applied as the trigger signal to the trigger terminal TI1. In this case, slow playback is performed to continuously move the video tape by one frame. In other words, the repetition time of the frame reproduction is arbitrarily set by the time constants of the variable resistor VR1 and the condenser C1 to perform low speed reproduction. On the other hand, in the case of the stop playback, as in the low speed playback, one frame movement is repeatedly performed according to the stop playback signal ST, and then the still playback is performed by maintaining the stop state, and playback is performed while moving the frame playback by only one frame. It will stop after executing.

However, such a conventional capstan motor control circuit uses only the control signal CTL reproduced from the video tape, so the accuracy of the driving signal of the capstan motor M1 becomes a problem, and the driving and stopping of the capstan motor M1 is prevented. Since the capstan motor (M1) is driven in the reverse direction in order to configure the circuit for fast response, it is rapidly braked, but the actual response state of the capstan motor (M1) with respect to the time of the reverse drive signal, that is, rotation of the capstan motor (M1) There was a defect that caused noise on the playback screen because the status could not be accurately determined.

In addition, two types of speed detecting devices are commonly used to detect the rotational state of the capstan motor M1, and the rotation of the capstan motor M1 is stabilized by detecting forward / reverse rotation. In addition to the need for a speed detecting element, there was a defect that requires a complicated direction detecting circuit.

In addition, two types of speed detecting elements are used to detect the rotational state of the capstan motor M1, and the rotation of the forward / reverse direction is detected to stabilize the reverse braking of the capstan motor M1. In addition to the need for a speed detecting element, there was a defect that requires a complicated direction detecting circuit.

In view of such a conventional defect, the present invention devises a control circuit of a simple configuration that accurately controls the driving of the capstan motor by using the control signal reproduced from the videotape and the speed detection signal detected according to the rotation of the capstan motor. If this is described in detail with reference to the accompanying drawings 3 and 4 as follows.

3 is a control circuit diagram of the present invention. As shown therein, the mode selection terminal MS1 of the microprocessor 12 to which the head switching signal HS of 30 Hz and the speed detection signal CFG through the amplifier 11 are input. -Slow playback, stop playback, and frame playback switches SW1-SW3 are connected to MS3) to connect the drive control signal output terminal DV1 to the input terminal of the mono multi 14, and to connect the connection point to the resistor R15. Is connected to the base of the resistor R16 and the transistor TR11, and the collector of the transistor TR11 is connected with the reproduction control signal CTL through the amplifier 13 and the resistor R16. Connected to an input terminal, the output terminal of the multi-multiplicity 14 (15) terminal of the speed detection control signal output terminal of the microprocessor 12 through a resistor (R17) (R18) and a diode (D11) (D12) CFO1) (CFO2) input terminals of monomulti (16) (17) connected to trigger terminals (TI16) (TI17) with time constant circuits (19) and (20) Output terminal of the monomulti (16) and (17) through the diode (D13) and (D14), and the driving terminal of the capstan motor driving section (22) together with the constant speed control signal (PL) through the diode (D15). And the output terminals of the monolithic 16 and 17 via the diodes D13 and D14 to the base of the resistor R20 and the transistor TR12 through the resistor R19. The collector of the transistor TR12 is connected to the base of the transistor TR13 together with the drive control signal output terminal DV2 of the microprocessor 12 through the resistor R21, and connects its collector to the drive terminal DR. On the other hand, the output terminal of the monomulti 17 is connected to the base of the transistor TR14 via the resistor R22, and the collector of the transistor TR14 is connected to the forward / reverse control signal F through the resistor R23. Of ) And forward / reverse control terminals of the capstan motor drive section (FD / ) Is configured.

If described in detail with reference to the waveform diagram of Figure 4 the effect of the present invention configured as described above.

The power is applied to the power supply terminal Vcc, and the high speed constant speed control of the driving terminal DR and the forward / reverse control terminal FD / RD of the capstan motor driving unit 22 is shown in Figs. Signal (PL) and forward / reverse control signal (F / If the low speed regeneration switch SW1 is shorted at time t1 while the capstan motor driving unit 22 drives the capstan motor M11 at constant speed, the microprocessor 12 outputs the drive control signal output terminal DV2. As shown in FIG. 4C, the high potential is output to the base of the transistor TR13 through the resistor R21, and the transistor TR13 is turned on so that the constant speed control signal of the high potential PL) is grounded through the transistor TR13, and accordingly, a low potential is applied to the driving terminal DR of the capstan motor driver 22 as shown in FIG. 4A, so that the capstan motor driver 2 is capstan. The driving of the motor M11 is stopped.

In this state, when the 30 Hz head switching signal HS input to the microprocessor 12 is converted from the low potential to the high potential, as shown in FIG. 4D, the microprocessor 12 has its drive control signal output terminal DV1. As shown in Fig. 4e, the low potential is output and input to the input terminal of the monomulti 14. Accordingly, in the mono multi 14, the time constant circuit 18 of the time constant circuit 18 is shown in Fig. 4f. When the low potential is output during the time constant time T1 and the time constant time T1 has elapsed and the output signal of the monomulti 14 goes from low potential to high potential, the power supply of the power supply terminal Vcc becomes a time constant circuit ( As shown in FIG. 4g through the resistor R12 of FIG. 19, the capacitor C13 is charged to the trigger terminal TI16 of the monomulti 16 as shown in FIG. As shown in the figure, a high potential is output, and this high potential is obtained by the diode D13 and Since it is applied to the base of the transistor TR12 through the term R19, the transistor TR12 is turned on so that the transistor TR13 is turned off, and accordingly, the high potential output from the monomulti 16 is applied to the diodes D13 and D15. As shown in FIG. 4A, the capstan motor driver 22 drives the capstan motor M11 in the forward direction so that the tape may be driven by being applied to the driving terminal DR of the capstan motor driver 22.

In this state, as shown in FIG. 4I, the speed detection signal CFG of the capstan motor M11 is detected and input to the microprocessor 12 through the amplifier 11 as the capstan motor M11 is driven. The microprocessor 12 counts the speed detection signal CFG, and the speed at which the number of the counted speed detection signals CFG reaches a constant number N1, that is, the capstan motor M11 reaches the normal speed. The number N1 of the detection signals CFG is counted, and the microprocessor 12 outputs a low potential to the drive control signal output terminal DV2 to turn off the transistor TR13 as shown in FIG. 4C. Output the high potential pulse signal to the speed detection control signal output terminal CFO1 as shown in FIG. 4j and charge the capacitor C13 through the resistor R17 and diode D11 as shown in FIG. 4g. do. As a result, at time t2, the monomulti 16 is charged in the capacitor C13 as shown in FIG. 4G. Accordingly, at time t2, the monomulti 16 outputs a low potential as shown in FIG. 4h, and accordingly, the drive terminal DR of the capstan motor driving unit 22 has a high voltage as shown in FIG. 4a. The constant speed control signal PL is applied to drive the capstan motor M11 at constant speed.

In this state, when the control signal CTL is reproduced on the videotape and input to the multi-level 15 through the amplifier 13 and the resistor R16, as shown in FIG. 4k, the power supply of the power supply terminal Vcc. Through the variable resistor VR1 of the time constant circuit 20, the capacitor C12 is charged and applied to the trigger terminal TI15 of the monomulti 15 as shown in FIG. When the low potential is outputted as shown in FIG. 4m at the output terminal of FIG. 4 and the time constant time T2 of the time constant circuit 20 elapses, the high potential is output from the monomultiplex 15 so that the monomultiplex 17 As shown in FIG. 4C, the processor 12 outputs a high potential to the drive control signal output terminal DV2 as shown in FIG. 4C, and the speed detection control signal output terminal CFO2 as shown in FIG. 4B. Outputs a pulse signal to the capacitor C14 as shown in FIG. 4n through the resistor R18 and the diode D12. As it is charged, at time t3, the monomulti 17 outputs a low potential as shown in FIG. 4A to turn off the transistor TR12, and the transistor TR13 is output from the drive control signal output terminal DV2. Since the low potential is applied to the driving terminal DR of the capstan motor driving unit 22 by the high potential as shown in FIG. 4A, the capstan motor driving unit 22 stops the driving of the capstan motor M11. The reproduction of one frame is completed, and at this time, the transistor TR16 is turned off by the low potential output from the monomulti 17 so that the forward / reverse control terminal FD / of the capstan motor driver 22 can be turned off. A high potential is applied as shown in FIG. 4B.

This operation is performed continuously according to the period of the signal output to the drive control signal output terminal DV1 of the microprocessor 12 to perform the low speed reproduction.

The number of speed detection signals CFG is 25 in the SP mode in the NTSC mode, 12 and 8 in the LP and EP modes, respectively, and N1 is approximately. It is enough.

When the stop playback switch SW2 is pressed in the above manner, as in the description of the low speed playback, the playback of one frame is repeatedly performed, and then the stop playback is performed and the frame playback switch SW3 is shorted. In the same manner as described in the low speed playback, the playback stops after one frame is played back.

As described in detail above, the present invention precisely controls the forward and reverse driving time of the capstan motor by using the capstan motor speed detection signal as well as the control signal reproduced from the videotape during the shift playback. It will have the effect of reducing it.

Claims (1)

The head switching signal HS and the speed detection signal CFG of the capstan motor M11 are connected to the microprocessor 12 connected to the mode selection terminals MS1-MS3 at low speed and stop, and the frame reproducing switch SW1-SW3 is connected. And a drive control signal output terminal DV1 for outputting a drive control signal in accordance with the head switching signal HS to the input terminal of the mono multi 16 through the mono multi 14. The speed detection signal CFG is connected to the trigger terminals 16 and 17 of the mono multi 16 and 17 together with the regeneration control signal CTL connected to the base side of the TR1 and the collector 13 through the amplifier 13. Is connected to the speed detection control signal output terminals (CFO1), (CFO2) side and time constant circuits (19) (21) of the microprocessor (12) for outputting a pulse signal when a predetermined number (N1), (N2) is After connecting the output terminal of the mono-multi 21 to the base side of the transistor TR14, the collector thereof is connected to the forward / reverse control signal (F /). ) / Forward control terminal (FD / ), And the output terminals of the monolithic 16 and 17 terminals are connected to the base side of the transistor TR12, and the collector of the transistor TR12 is the drive control signal output terminal of the microprocessor 12. After connecting to the base of the transistor TR13 together with the (DV2) side, the collector thereof is connected to the output terminal side of the monolithic 16 and 17 and the driving terminal of the capstan motor driving unit 22 together with the constant speed control signal PL. And a capstan motor control circuit for shift reproduction.