KR900008859Y1 - Screen searching control for vcr - Google Patents

Abstract

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Description

Screen navigation control circuit of video cassette recorder

1 is a screen navigation control circuit diagram of the present invention.

A-k of FIG. 2 is a waveform diagram of each part of FIG.

* Explanation of symbols for main parts of the drawings

1, 2: Differentiation 3: Microcomputer

MM1-MM4: Monomulti FF1, FF2: Flip-flop

PC1, PC2: Photocoupler AND1-AND8: ANDGATE

OR1-OR4: Oagate SW1: FF / CUN switch

SW2: REW / REV Switch SW3, SW4: Analog Switch

PBH: Constant speed playback signal input terminal

The present invention relates to a screen navigation control circuit of a video cassette recorder in which a video cassette recorder searches a screen at high speed, that is, controls fast forward playback (CUE) and backward fast playback (REV).

In conventional video cassette recorders, if the FF (fast forward) / CUE switch or REW (rewind) / REV switch is pressed without pressing the PB switch, FF or REW the video tape If you press the FF / CUE or REW / REV switch in the state of 'CUE' or 'REV', you can stop the CUE or REV by releasing the pressed FF / CUE or REW / REV switch. In order to do so, it is necessary to press the FF / CUE or REW / REV switch continuously.

The present invention, in view of such a conventional defect, when pressing the FF / CUE or REW / REV switch in the state of constant speed playback, the CUE or REV, and pressing the FF / CUE or REW / REV switch once again, the CUE Alternatively, REV is conceived to lock (hereinafter, abbreviated as CUEL and REVL), which will be described in detail with reference to the accompanying drawings.

FIG. 1 is a screen navigation control circuit diagram of the present invention. As shown therein, the FF / CUE and FF / REV switches SW1 and SW3 connected to the power supply terminal Vcc together with the constant speed playback signal input terminal PBH are shown in FIG. Connect the input terminal of the mono multi (MM1) (MM3) through the AND gate (AND1) (AND5), and flip-flop (FF1) the output terminal of the mono multi (MM1) (MM3) through the differentiator (1) (2). Connected to the input terminals T1 and T2 of the FF2 and output terminals of the flip-flop FF1 and FF2. Is connected to one input terminal of the OR gate OR1 (OR3) through an AND gate AND2 (AND6) and an analog switch SW2 (SW4) together with the constant speed reproduction signal input terminal PBH. Q1) (Q2) is connected to the control terminal of the analog switch SW3 (SW4) through the AND gate AND3 (AND7) and the monomulti (MM2) (MM4) together with the constant speed reproduction signal input terminal PBH. The output terminals Q1 and Q2 are connected to the other input terminal of the ORG OR1 OR3 through the AND gate AND4 AND8 together with the output terminals of the AND gate AND1 AND5. The output terminals of the OR gates OR1 and OR3 together with the switches SW1 and SW3 are connected to the photocoupler PC1 and PC2 through the OR gates OR2 and OR2 and the resistors R1 and R2. Is connected to the light emitting diodes PD1 and PD2, and the collectors and emitters of the phototransistors PTR1 and PTR2 of the photocoupler PC1 and PC2 are stroboscopic terminals ST1 and ST2 of the microcomputer 3, respectively. And kiss can terminals (KS1) (KS2) In this case, the high potential is input to the constant speed playback signal input terminal PBH when the video cassette recorder is played by pressing the PB switch, and the analog switches SW2 and SW4 have a high potential at their control terminals. When it is applied, it is short-circuited, and when the signal of the strobe terminal (ST1) (ST2) is input to its kisscan terminal (KS1) (KS2) when it is not in the PB state, the video cassette recorder is FF and REW. In the PB state, when the signals of the stroboscope terminals ST1 and ST2 are input to the kisscan terminals KS1 and KS2, CUE and REV are performed.

When described in detail with reference to the waveform diagram of Figure 2 the effect of the present invention configured as described above.

When the power is applied to the power supply terminal Vcc and the low potential is input to the constant speed playback signal input terminal PBH without PB without pressing the PB switch, as shown in FIG. When the FF / CUE switch SW1 is pressed and shorted, the power supply of the power supply terminal Vcc is applied to one input terminal of the oragate OR2 through the switch SW1, so that the oragate OR2 is shown in FIG. As shown in the figure, the high potential is output, and the output high potential is applied to the light emitting diode PD1 of the photocoupler PC1 through the resistor R1 so that the light receiving transistor PTR1 is turned on. The pulse signal output from the strobe terminal ST1 of (3) is input to the kisscan terminal KS1 through the light receiving transistor PTR1, and the microcomputer 3 performs FF.

In this state, the PB switch is pressed at time t2, and the high potential is input to the constant speed playback signal input terminal PBH as shown in Fig. 2A, and the switch is performed at time t3. When SW1 is pressed and shorted, the power of the power supply terminal Vcc is input to the AND gate AND1 together with the high potential of the rear input terminal PBH through the switch SW1, and the AND gate AND1 is connected to (Fig. As shown in c), the high potential is output, and the output high potential is input to one input terminal of the AND gate AND4 and the mono multi MM1, so that the mono multi MM1 is shown in (d) of FIG. As shown in the figure, a pulse signal having a predetermined width is output, and the output pulse signal is differentiated as shown in the second (e) through the differentiator 1, and then the input terminal T1 of the flip-flop FF1. Is applied to the flip-flop FF1 to the output terminal Q1. As shown in (f) (g) of FIG. 2, the high potential and the low potential are respectively output.

When the high potential is output from the output terminal Q1 as described above, the output high potential is input to the AND gate AND3 together with the high potential of the input terminal PBH, and the AND gate AND3 is shown in FIG. 2 (h). As shown in the figure, the high potential is output, and the mono-multi (MM2) also outputs the high potential as shown in (i) of FIG. 2 so that the analog switch SW2 is shorted, and the high output output from the output terminal Q1. Since the input is input to the AND gate AND4 together with the high potential output from the AND gate AND1 as described above, the AND gate AND4 outputs the high potential as shown in FIG. The high potential is applied to the light emitting diode PD1 through the OR gate OR1 (OR2) and is applied to the light emitting diode PD1 through the resistor R1, and the light receiving transistor PTR1 is turned on so that the microcomputer 3 becomes CUE. .

In this state, when the switch SW1 is removed and opened at the time 14, the low potential is output from the AND gate AND1 and AND4 and the low potential is output from the OR gate OR1 OR2. The light emitting diode PD1 is turned off and the light receiving transistor PTR1 is turned off so that the microcomputer 3 stops the CUE, i.e., only the time t3-t4 is shorted by pressing the switch SW1.

When the switch SW1 is pressed and shorted at the time t5 in such a state, the high potential is output from the AND gate AND1 as shown in FIG. As shown in (d) of FIG. 2, a pulse signal having a predetermined width is output and differentiated as shown in (e) of FIG. 2 through the differentiator 1, and then to the input terminal T1 of the flip-flop FF1. Output terminal Q1 of flip-flop FF1 As shown in Fig. 2 (f) (g), the low and high potentials are respectively output, and the output terminal The high potential of is input to the AND gate AND2 together with the high potential of the input terminal PBH, and the AND gate AND2 outputs the high potential as shown in (k) of FIG. Since the high potential output from the mono multi MM2 is applied to the control terminal of the switch SW2 as described above, the high potential output from the AND gate AND2 passes through the analog switch SW2, and the oragate ( It is applied to the light emitting diode PD1 through OR1 and OR2 and the resistor R1 and is equalized so that the light receiving transistor PTR1 is turned on and the microcomputer 3 makes the CUE, at which time the switch SW1 is at time t6. Output terminal of flip-flop (FF1) Since the high potential is continuously output from the light-receiving transistor (PTR1) continues to be on state, the microcomputer (30) continues to CUE, that is, CUEL.

In this state, if the switch SW1 is short-circuited at time t7, the pulse signal is inputted to the flip-flop FF1 as described above, and its output terminal Q1. Because the high potential and low potential are output at, the high potential is output from the AND gate AND4 and the OR gates OR1 and OR2 as described above, the light emitting diode PD1 is turned on, and the light receiving transistor PTR1 is turned on to continue. When the switch SW1 is opened, the low potential is output from the AND gates AND2 and AND4, the low potential is output from the OR gates OR1 and OR2, and the light emitting diode PD1 is disturbed. The light receiving transistor PTR1 is turned off to stop the CUE.

That is, if the switch SW1 is short-circuited in the PB state, CUE is performed only for the shorted time, and if the switch SW1 is short-circuited again, the CUE continues to be cued even if the switch SW1 is opened, and the switch ( When SW1) is shorted, CUE is repeated only during the shorted time, and the switch (SW1) is shorted to repeat CUE and CUEL.

In addition, the microcomputer 3 performs the REW operation by shorting the switch SW1, and in the PB state, the REV and REVL are repeatedly performed by shorting the switch SW3.

As described above, the present invention repeats CUE or REV and CUEL or REVL in response to pressing the FF / CUE or REW / REV switch in PB state. Pressing has the effect of reducing the user's hassle.

Claims (1)

FF.CUE and REW / REV switch (SW1) in the screen navigation control circuit which performs CUE and REV as the strobe terminal ST1 (ST2) of the microcomputer 3 is input to the kisscan terminals KS1 (KS2). (SW3) of the flip-flop (FF1) (FF2) through the AND gate (AND1) (AND5) and mono-multi (MM1) (MM3), the differentiator (1) (2) together with the constant speed reproduction signal input terminal (PBH). It is connected to the input terminal T1 (T2), and its output terminal Is connected to one input terminal of the OR gate OR1 OR3 through an AND gate AND2 AND6 and an analog switch SW2 SW4 together with the input terminal PBH, and an output terminal Q1 ( Q2) is connected to the control terminal of the switch SW2 (SW4) through the AND gate AND3 (AND7) and the monomulti (MM2) (MM4) together with the input terminal PBH, and the output terminal Q1) and Q2 are connected to the AND gate AND1, and the output terminals of the OR gates OR1 and OR3 together with the switches SW1 and SW3 are connected to the OR gate OR2 OR4 and the photocoupler PC1. And (2) connected to the stroboscope terminal (ST1) and the scanning terminal (KS1) (KS2) via a PC2.