KR850001693B1 - Channel bar display circuit - Google Patents

Abstract

Each channel is displayed througth the bar display of a T.V. receiver. The position of the bar is changed according to the tuning voltage and the color of bar is changed according to the band (UHF,VHF). When it is off the air, the channel number at that time is displayed conversely, and when it is on the air, the bar disappears automatically and the normal screen can be received. The channel up, down switches(S1,S2) are composed so that Q2 is set according to the presence of the image signal. The state signal of the flip flop circuit(Q2), the signal comparator(Q3) and the saw- toothed wave are transmitted to the signal control part.

Description

Channel Bar Display Circuit

1 is a circuit diagram of the present invention.

2 is a waveform characteristic diagram of the circuit of the present invention.

* Explanation of symbols for main parts of the drawings

10: VHF tuner power supply circuit 20: UHF tuner power supply circuit

30: constant voltage circuit (B ⁺ ) 40: registered pulse circuit

50: full-back pulse circuit 60: AFC circuit

70 tuner tuning voltage supply circuit 80 red image output circuit

90: green video output circuit S ₁ : down switch

S ₂ : Up switch R ₁ -R ₂₅ : Resistance

VR _{1 to} VR ₅ : Variable resistance C _{l to} C ₉ : Capacitor

D _{1 to} D ₁₇ : Diode TR ₁ : Transistor

Q ₁ : Signal control unit Q ₂ : Flip-flop circuit

Q ₃ : Signal comparison Q ₄ : NAND gate

The present invention relates to a channel bar (BAR) display circuit of a TV receiver using an automatic tuning tuner.

In a typical TV receiver, the channel display circuit displays channel numbers and light emitting diodes on the left and right are displayed on the light emitting diodes as the channel is changed, or an indicator of channel number display is attached when the channel is changed by attaching an indicator of the channel number display. Was to change.

However, according to the present invention, a flyback pulse is obtained by varying the bar position according to the tuning voltage and changing the color of the bar according to each band (UHF, VHF) to display each channel by the bar display on the receiver screen. After the pulse of the circuit is made into a sawtooth pulse, the tuning voltage is applied to the signal control unit by applying the tuning pulse waveform, the signal comparison unit, and the flip-flop circuit pulse waveform to vary the amplitude of the sawtooth pulse. To control the channel bar to display on the abstract.

This will be described below with reference to the accompanying drawings.

In the channel up and down switches S ₁ and S ₂ of the present invention, the grounded state signal is applied when the switch is connected to the signal control unit Q ₁ , the flip-flop circuit Q ₂ , and the new comparison unit Q ₃ . The state signal of the synchronous pulse circuit 40 which applies the image signal only when the flyback pulse circuit 50 and the image signal are applied is applied to the signal comparator Q ₃ through the NAND gate Q ₄ . According to the presence or absence of the video signal, it is applied as a pulse to the signal control unit Q ₁ and the flip-flop circuit Q ₂ so that the flip-flop circuit Q ₂ is set according to the presence or absence of the synchronization signal to detect the presence or absence of the video signal. The signal control unit is configured to transmit the state signal of the flip-flop circuit Q ₂ and the signal comparing unit Q ₃ and the state signal of the sawtooth wave through the transistor TR ₁ in the UHF and VHF tuner supply circuits 10 and 20. (Q ₁₎ of each voltage band of the tuner and the diode (D ₆₎ and adapted to be applied to the (D ₇₎ (D ₈₎ controls the tuner copper The voltage supply circuit 70, the red video output circuit 80, green image output circuit 90 is configured to be applied.

The effect of the present invention configured as described above is as follows.

The pulse from the flyback pulse circuit 50 is appropriately attenuated by the resistor R ₂₃ , the capacitor CP, and the resistor R ₂₅ to the transistor TR ₁ through the diode D ₁₅ . When applied, the diode D ₁₅ conducts only during the pulse period so that the conducting pulse voltage is charged in the capacitor C ₁ .

When the VHF is received at the base of the transistor RR ₁ , the VHF tuner power supply circuit 1 receives the voltage B ⁺ and the UHF tuner power supply circuit 20 becomes OV, so that the diode D _l and the resistor R _{l are applied} . Forward bias is applied to the base of transistor (TR ₁ ) through variable resistor (VR ₁ ), resistor (R ₃ ), diode (D ₂ ), and when receiving UHF, voltage (B ⁺ ) only in UHF tuner power supply circuit (20). Therefore, forward bias is applied to the base of the transistor TR _l through the diode D ₁₀ , the resistor R ₂ , the variable resistor VR ₂ , the resistor R ₃ , and the diode D ₂ .

Therefore, the charging voltage charged to the capacitor (C _l) is as a constant-current discharge due to the bias voltage of the transistor (TR ₁₎ when the pulse duration over a diode (D ₁₆₎ is blocked.

After the discharge, the capacitor C ₁ is charged through the diode D ₁₅ again when the next pulse comes in. After the pulse period, the capacitor C ₁ discharges and a sawtooth waveform like the second (a) is generated in the transistor TR ₁ collector. do.

At this time, if the variable resistance (VR ₁ ) (VR ₂ ) is adjusted, the bias voltage at VHF and UHF changes, so the discharge current is changed. If the bias voltage is high, the generation current increases and the amplitude of the sawtooth wave increases, and the discharge current decreases when the bias voltage is high. The amplitude of the sawtooth wave is reduced.

The sawtooth voltage waveform generated in this way is applied to the terminal 5 of the control signal portion Q ₁ through the capacitor C ₂ .

On the other hand, the DC voltage of the terminal 5 of the control signal unit Q ₁ is tuned because the tuning voltage is divided and applied by the resistors R ₁₆ (R ₅ ) and R ₆ in the tuner tuning voltage supply circuit 7. It is variable in proportion to the voltage.

Therefore, the waveform of the control signal part Q ₁ terminal 5 becomes as shown in FIG. 2 (b). When the tuning voltage is increased, the overall DC level is increased, and when the tuning voltage is lowered, the overall sawtooth waveform is lowered.

However, when the tuning voltage rises to the high and low voltage recognition voltage lines of the control signal part Q ₁ terminals 5 and 6, the voltage of the lower part of the sawtooth wave is applied, and the sawtooth wave is gradually lowered. The upper voltage is gradually applied.

If the tuning voltage is low, it may be OV. In this case, the sawtooth wave may be less than or equal to the control signal unit Q ₁ terminals 5 and 6, the high potential, and the low potential recognition voltage line.

Therefore, in order to compensate for this, in the case of VHF reception, the power source B ⁺ is divided into a resistor R ₇ , a variable resistor VR ₃ , and a resistor R _ll , and thus, at the midpoint of the variable resistor VR ₃ . Since the diode D ₃ and the resistor Rs are connected to the signal control unit Q ₁ terminals 5 and 6, the tuning voltage is low, so that the DC voltage of the control signal unit D ₁ terminals 5 and 6 is reduced. When the voltage is low, the diode D ₃ is turned on so that the voltage obtained by dividing the power source B ⁺ is applied to the control signal part Q ₁ terminals 5 and 6 through the diode D ₃ , and thus the voltage is increased. The voltage can be changed by adjusting the variable resistor VR ₃ .

In addition, when receiving UHF the resistance (Rp), a variable resistor (VR _4), the resistance is a power supply (B ⁺⁾ divided by (R _ll) diode (D ₄₎ at the midpoint of the variable resistors (VR _4), the resistance ( Rs) is connected to the signal control unit (Q ₁ ) terminals (5) (6), so when the tuning voltage is lowered, the diode (D ₄ ) is turned on and the power supply (B ⁺ ) is divided so that the diode (D ₄ ), the resistor (Rs) a signal control unit (Q _1), the terminal 5 is also connected to (6) becomes higher the DC voltage to the signal control (Q _1), the terminal (5) and (6) At this time, the voltage of the via is an optionally by adjusting the variable resistor (VR ₄₎ You can change it.

Eventually, the variable resistor (VR ₃ ) (VR ₄ ) is adjusted so that the sawtooth waveform is applied to the high and low potential recognition voltage lines of the signal control unit (Q ₁ ) and the terminals (5) and (6) in the range of VHF and UHF full tuning voltage. It can be done.

In this state, when the tuning voltage is examined at a low voltage, the distance T of the high and low potential recognition voltage lines of the signal control unit Q ₁ and the terminals 5 and 6 during the sawtooth discharge is shown in FIG. 2 (b). It grows bigger as

At this time, if the signal control unit (Q ₁ ) terminal (5) (6) voltage is less than the high potential, low potential recognition voltage, it becomes a low potential state (Low), if it is above a high potential state (High) and the signal control unit (Q ₁ ) terminal (2) and (4) outputs a pulser type as shown in FIG. 2 (c).

The NAND gate input / output terminal outputs a high potential signal regardless of the input voltage of the other input terminal when one terminal is in a low potential state. A pulse waveform is applied to the signal control unit Q _l terminal 2 so that the signal control unit In order for the pulse waveform to come out of the terminal (3) of (Q ₁ ), the signal control unit (Q ₁ ) terminal (1) must be in a high potential state unconditionally.

In addition, when viewing the normal screen, the bar should not appear in the middle of the screen, except when there is no reception screen, and when the tuning voltage is up or down, there is a signal control unit Q ₁ terminal (1). ) Should be the high potential signal, and when there is a receiving screen, the signal control unit (Q ₁ ) terminal (1) should be in the low potential state.

Thus, signal control (Q ₁₎ terminal (1) is a high potential state if the signal control (Q ₁₎ terminals 3 are signal control (Q ₁₎ terminal status (2) is a low potential state, and the high potential state high potential Then, the inverted signal that becomes the low potential becomes as shown in the second (d). At this time, the sawtooth wave becomes a pulse voltage that becomes a high potential only in a period T between the high and low potential recognition voltages of the signal control unit Q ₁ terminals 5 and 6.

The pulse voltage is a differential circuit capacitor (C ₃₎ and a resistor (R _l3) of the differential at the input of the passing signal control (Q _1), the terminal 12 13 is As shown in Fig claim 2 (e) immediately after the T period Only for a while, the signal control unit Q ₁ becomes below the high potential and low potential recognition voltage of the terminals 12 and 13 to become a low potential state signal, and the rest of the period becomes a high potential state so that the signal control unit Q ₁ terminal ( The output of 11) becomes a narrow pulse waveform as shown in FIG. 2 (f).

When receiving the VHF, when the pulse waveform of the signal control unit Q ₁ terminal 11 is a low-potential state signal in which no pulse is emitted, the diode D ₆ is turned on so that the anode voltage of the diode D ₆ drops and the diode ( D ₇ ) has a reverse voltage and it is cut off so that it does not affect the video output at all. However, during the pulse period, i.e., the high potential signal, the diode D ₈ is cut off due to the reverse voltage, and the power source B ⁺ in the VHF power supply circuit 10 turns the diode D ₇ through the resistor R ₈ . It will be conducted.

Accordingly, the base waveform of the red image output circuit 80 at this time becomes as shown in FIG. 2 (h), and the red signal becomes strong only when the signal control unit Q ₁ terminal 11 is in a high potential state. A red bar comes out.

At this time, if the tuning voltage increases, the distance T increases, so the distance T is increased from the left side of the receiver screen, and if the tuning voltage decreases, the T decreases, so the bar appears closer to the left side of the receiver screen.

If the pulse waveform has a low potential of the signal control section (Q ₁₎ terminal 11 during UHF reception, since the diode (D ₅₎ that conducts the anode voltage of the die Alliance (D ₈₎ away from the diode (D ₈₎ are blocked It will not affect the video output at all. However, in the period during which the signal control unit Q ₁ terminal 11 becomes a high potential state signal, the diode D ₅ is cut off so that the power source B ⁺ in the UHF power supply circuit 20 passes through the resistor R ₁₀ . (D ₈ ) is conducted.

Therefore, the base waveform of the green image output circuit 90 at this time is as shown in FIG. 2 (h), and the green signal is strong only when the signal control unit Q ₁ terminal 11 becomes high potential, so that a green bar appears on the receiver screen. .

At this time, if the tuning voltage is increased, the distance T increases as in the case of receiving the VHF, and thus the distance T increases from the left side of the receiver screen. If the tuning voltage decreases, the distance T decreases, so that the closer to the left side of the receiver screen.

On the other hand, in the synchronous pulse circuit 40, the synchronous pulse circuit is appropriately attenuated by the resistor R ₂₂ capacitor C ₈ , applied to the NAND gate Q ₄ terminal 1, and a pulse is generated in the flyback pulse circuit 50. The resistors R ₂₃ and R ₂₅ are appropriately attenuated through the capacitor C ₉ and applied to the NAND gate Q ₄ terminal 2. At this time, the diode (D ₁₆ ) (D ₁₇ ) is to cut the secondary component.

However, since the synchronous pulses come in when there is a broadcast signal, and there is no broadcast signal, all of them are OV and flyback pulses are generated regardless of the broadcast signal. If there is no broadcast signal, the NAND gate (Q ₄ ) terminal is in a low potential state. Regardless of the gate Q ₄ terminal 2, the NAND gate Q ₄ terminal 3 becomes a high potential.

The voltage comparator (Q ₃ ) terminal (1) (2) has a high potential through the variable resistor (VR ₅ ) and resistor (R _2l ), so that the signal comparison unit (Q ₃ ) terminal (3) is in a low potential state. The signal control unit Q ₁ terminal 9 is in a low potential state.

Therefore, the signal control unit Q ₁ terminal 10 becomes a high potential, and the signal control unit Q ₁ terminal 1 becomes a high potential state signal through a diode D ₉ and a resistor R ₁₄ , and a bar comes out.

If there is a broadcast signal, the synchronous pulse enters the NAND gate Q ₄ terminal 1, so that the waveform of the NAND gate Q ₄ terminal 3 is the same waveform as the second (i) diagram where only the synchronous pulse period becomes low potential. Becomes

When the NAND gate Q ₄ terminal 3 is at high potential, the capacitor C ₇ is charged through the variable resistor VR ₅ and the resistor R _21. When the NAND gate Q ₄ is at a low potential, the capacitor C ₇ is charged. Since the silver discharges through the diode (D ₁₄ ), the capacitor (C ₇ ) voltage is lower than when the NAND gate (Q ₄ ) terminal (3) is still in a high potential state, and this voltage can be adjusted by the variable resistor (VR ₅ ).

When the variable resistor (VR ₅ ) is adjusted and the capacitor (C ₇ ) voltage has a synchronous pulse, the signal comparator (Q ₃ ) terminal (1) (2) is below the high and low potential recognition voltage and there is no synchronous pulse. If the signal comparator (Q ₃ ) terminal (I) (2) is adjusted above the low high potential and low potential recognition voltage, the output of the signal comparator (Q ₃ ) terminal 13 has a broadcast signal and there is a synchronization signal. the status signal comparing unit (Q _3), the terminal (1) and (2) above, so that the low potential and is a classic low-potential state signal Dunn not have a broadcasting signal.

Signal comparing unit (Q _{3) The} terminal 3 is when the low potential (broadcast signal is no) signal control (Q ₁₎ regardless of the signal control section (Q ₁₎ terminal 10 to the terminal 8 is a high potential bar (bAR) is naohjiman signal control (Q _1), the terminal (3) there is a broadcast signal when the high potential to the signal control section (Q ₁₎ terminal 8 are signal control (Q _1), the terminal (10 only when the low-potential ) Is the high potential bar will come out.

On the other hand, when the UP switch S ₂ is pressed, the terminal 8 of the flip-flop circuit Q ₂ has a low potential, the terminals 10 and 12 have a high potential, and the terminal 13 has a high potential. 11) (9) becomes low potential and terminal 9 is in low potential, so terminals 11 and 12 are set to high potential and terminals 9 and 11 are set to low potential regardless of terminal 8. do.

And since terminal 1 has low potential, terminals 3 and 6 have high potential, and terminal 5 has high potential (no terminal has a broadcast signal, terminal 9 of Q ₃ has low potential, so terminal 10 of Q ₃ the high potential and the Q ₂ terminal 5 through R ₁₇ is a high potential) terminal 2, 4 is a low-potential terminal (2) is a low potential terminal (1) has the high potential and low potential Regardless of the signal, terminals (3) (6) are at high potential and terminals (2) (4) are at low potential so that the signal comparison unit (Q ₃ ) terminal 5 is a high potential, signal comparison unit (Q ₃ ) terminal ( 6) the low potential, the signal comparison unit (Q ₃ ) terminal 4 and the signal control unit (Q ₁ ) terminal 18 is a low potential, the signal control unit (Q ₁ ) terminal 10 becomes a high potential Come out. However, at this time, when there is a broadcast signal and a synchronization signal comes in, as described above, the priority signal comparing unit (Q ₃ ) terminal 3, the signal comparing unit (Q ₃ ) terminal 12, and the signal comparing unit (Q ₃ ) terminal 9 ) Becomes a high potential state.

Therefore, when the synchronization voltage is up and the synchronization is established, the frequency increases and then the synchronization signal is acquired. Therefore, the AFC voltage is adjusted to be high potential, so the signal comparison unit (Q ₂ ) is adjusted. The terminal 8 becomes high potential and the signal comparison part Q ₃ terminal 10 becomes low potential.

Because this is a terminal (1) of the flip-flop circuit (Q ₂₎ terminals the same as (6), the flip-flop circuit (Q ₂₎ terminals 2 and 3 is the high potential flip-flop circuit (Q ₂₎ is the high-potential terminal (3) (6) becomes a low potential state.

When the terminal 6 is in the low potential state, the terminals 2 and 4 of the flip-flop circuit Q ₂ are set to high potential and the terminals 3 and 4 are set to low potential regardless of the input of the terminal 5. .

And terminal 6 a signal comparison unit (Q _3), the terminal 5 is the same as that of the signal comparison unit (Q ₃₎ terminal 5 also has a low potential The signal comparing unit (Q _3), the terminal 6 is low Because of the potential state, the terminals 4 and 8 are in a high potential state.

At this time, the terminal 9 is also because the high-potential state signal control (Q _1), the terminal 10 is a low potential signal control (Q ₁₎ terminal 3 of because the synchronizing signal signal control (Q ₁₎ is always the high potential The differential wave form does not appear in the signal control unit Q ₁ terminal 12 so that the bar does not appear. In other words, if there is a broadcast signal while the reception frequency is increased, the bar of the screen is automatically disappeared, so that a stable screen can be seen.

When the DOWN switch S ₁ is pressed, both ends of the switch S ₁ are momentarily grounded, and thus each terminal of the flip-flop circuit Q ₂ operates as follows.

Terminal 5 low potential, terminals 2 and 4 are high potential and terminal 1 is high potential, so terminals 3 and 6 are low potential and terminal 6 is low potential and terminal 5 Regardless of the high potential and the low potential signal, terminals 2 and 4 are set to high potential, terminals 3 and 6 are set to low potential, terminal 13 is low potential, and terminals 9 and 10 are high potential. Since terminal 9 has a high potential (there is no synchronous signal, the terminal of Q ₃ has a high potential and the terminal 11 is also a high potential, so this voltage makes terminal 8 of Q _{2 high potential} through R ₂₀ ). ) Terminals 10 and 12 are at low potential and terminal 12 is also at low potential to input terminal 13

However, when the flip-flop circuit Q ₂ is thus down and the synchronization signal is input, the priority signal comparison unit Q ₃ terminals 3, 12, and 9 become high potential. When the synchronization voltage goes down and the synchronization is made, the frequency goes down and the synchronization signal gets better. Since the ACC voltage is adjusted to the low potential at this time, the signal comparison unit (Q ₃ ) terminal ( 8) becomes low potential and the terminals 10 and 13 are in a high potential state.

At this time, the signal comparator Q ₃ terminal 12 is in a high potential state, and the terminal 11 is in a low potential, and the terminal 8 of the flip-flop circuit Q ₂ is in a low potential state through a resistor R ₂₀ . Becomes So when the flip-flop circuit (Q _2), the terminal 10 12 is the terminal 13 of the high potential and the flip-flop circuit (Q ₂₎ it is because the high-potential terminal 11 9 is a pre-war above.

Therefore, since the terminal 9 has a low potential, the terminal 8 has a low potential of the flip-flop circuit Q ₂ terminal 9 regardless of the input condition, and the signal comparison part Q ₃ terminal 6 has a low potential. Since the signal comparison section Q ₃ terminal 5 is at low potential, the signal comparison section Q ₃ terminal 4 and the signal control section Q ₁ terminal 8 become high potential.

At this time, there is the synchronization signal control (Q ₁₎ terminal 4 is also because it is a high potential signal control (Q _1), the terminal 10 is a low potential signal control (Q ₁₎ terminal (1) since the low potential The signal control unit Q ₁ terminal 3 becomes an uninterrupted high potential and does not come out of the output of the differential circuit capacitor C ₃ and the resistor R ₁₃ so that the bar does not come out. In other words, if there is a broadcast signal while the frequency is down, the bar of the screen is automatically disappeared, so that a stable screen is seen.

As described above, the present invention can provide a channel bar display circuit for indicating that the bar is now present and whether there is a broadcast signal, and if there is a broadcast signal, the bar is automatically disappeared to receive a normal screen.

Claims (1)

UHF, VHF tuner power supply circuit connected to the transistor (TR ₁ ) by making a sawtooth pulse as a diode (D ₁₅ ), transistor (TR ₁ ), capacitor (C ₁ ) (C ₂ ) As the variable resistors VR ₁ and VR ₂ of (10) and (20), the base bias voltage of the transistor TR ₁ is varied to change the amplitude of the sawtooth wave, and the sawtooth pulse is converted into a resistor (R ₅ ) (R ₆ ) ( R ₇ ) (R ₈ ) (R ₁₆ ) and variable resistor (VR ₃ ) (VR ₄ ) to divide the tuning voltage and superimpose on DC voltage to compare signal (Q ₃ ) and flip-flop circuit (Q ₂ ) A channel bar display circuit for generating a channel bar of different channels by applying a waveform to the signal controller Q ₁ to control the band voltage of each tuner and the diodes D ₆ , D ₇ , and D ₈ .

Images