KR100309554B1 - The control current generating circuit of the amplifier - Google Patents

Abstract

The present invention relates to a control current generating circuit of an amplifier that varies the intensity of a control current when an internal temperature or an external temperature of the amplifier is varied so that the amplification of the amplifier is always constant. The present invention provides a circuit for compensating for a variation in temperature, and a circuit for detecting a malfunction of the temperature compensation of the amplifier and preventing the same.

According to another aspect of the present invention, there is provided a method for controlling an amplifying circuit, comprising: a user interface unit for outputting a variable control signal according to an amplification degree command signal input by a user; A voltage generator for generating a control voltage by dividing the temperature-compensated driving voltage according to the control signal input from the user interface unit; A current generator for generating a control current varying according to the control voltage applied from the voltage generator and providing the control current to the amplifier; A temperature sensing means for sensing a change in an external temperature and an internal temperature of the amplifier and outputting a temperature sensing signal; And a temperature compensating unit for receiving the temperature sensing signal input from the temperature sensing unit and outputting the temperature compensating driving voltage for compensating for a variation in amplification degree of an amplifier that varies according to temperature, .

Description

The control current generating circuit of the amplifier

The present invention relates to a circuit for generating a control current for controlling an amplification degree of an amplifier. More particularly, the present invention relates to a circuit for controlling the amplification degree of the amplifier by varying the intensity of the control current when the internal temperature or the external temperature of the amplifier is varied, To a current generating circuit.

Generally, amplifiers are commonly found in people's daily lives, such as audio amplifiers used in audio sets, video amplifiers used in television sets or video sets, amplifiers used in wireless communication terminals, Or amplifiers used in monitors, the use of amplifiers has become inevitable in almost all electrical appliances used by people.

Such an amplifier can be implemented using various semiconductor devices, and the semiconductor devices constituting the amplifier are susceptible to changes in the external environment. Particularly, the influence of the temperature is greatest. When the semiconductor device becomes hot or the external temperature changes by using the amplifier for a long time, the characteristics of the semiconductor devices change and the amplification degree of the amplifier changes.

Of course, in the case of a small-signal amplifier or an amplifier that does not require precision, the influence of temperature can be tolerated. However, in a video amplifier used for a video signal processor in which the signal amplitude varies from time to time or an amplifier requiring high precision, You have to compensate for the change. Particularly, in the case of an amplifier used in a video signal processor, which is located in an outer space such as a satellite, and has a strong variation in signal intensity, since there is no thermal current in the outer space, a change in temperature or heat generated in the amplifier may become stagnant The amplification degree of the amplifier is changed, and accurate video data can not be obtained.

It is an object of the present invention to provide a circuit for compensating for variations in amplification depending on an internal temperature or an external environment of an amplifier.

Another object of the present invention is to provide a circuit that allows a circuit to perform a minimum operation even if a situation occurs in which the temperature compensation of the amplifier malfunctions.

1 is a circuit diagram showing a control current generating circuit of an amplifier according to an embodiment of the present invention.

DESCRIPTION OF REFERENCE NUMERALS

10: user interface unit 20: voltage generating unit

30: current generator 40: amplifier

50: Temperature sensor 60: Temperature compensator

70: Circuit protection part

According to an aspect of the present invention, there is provided an apparatus for controlling an amplifying apparatus, comprising: a user interface unit for outputting a variable control signal according to an amplification degree command signal input by a user; A voltage generator for generating a control voltage by dividing the temperature-compensated driving voltage according to the control signal input from the user interface unit; A current generator for generating a control current varying according to the control voltage applied from the voltage generator and providing the control current to the amplifier; A temperature sensing means for sensing a change in an external temperature and an internal temperature of the amplifier and outputting a temperature sensing signal; And a temperature compensating unit receiving the temperature sensing signal input from the temperature sensing unit and outputting the temperature compensating driving voltage for compensating the amplification variation of the amplifier,

When the amplification degree of the amplifier changes according to the internal temperature or the external temperature, the control current supplied to the amplifier is varied to compensate for the change in the amplification degree according to the temperature change so that the amplification degree of the amplifier is constantly maintained regardless of the temperature .

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, a circuit for generating a control current for driving an amplifier includes a user interface unit 10 for outputting a control signal varying according to an amplification degree command signal input by a user, A voltage generator 20 for generating a control voltage by dividing the temperature-compensated driving voltage V _TC according to a control signal input from the voltage generator 20, A temperature sensor 50 for detecting a change in an external temperature and an internal temperature of the amplifier 40 and outputting a temperature sensing signal, receiving the inputted temperature detection signal amplified in the amplifier 40 to be varied according to the temperature is the temperature compensation section 60 for outputting a temperature compensation driving voltage (V _TC) for compensating for variations, temperature compensator (60) The temperature compensating unit And a circuit protection unit (70) for limiting a lower limit value and an upper limit value of the same voltage ( _VTC ).

A first diode array to connect here, the circuit protection unit 70 and the Vcc drive voltage anode terminal is limited to the lower limit of the temperature compensation drive voltage (V _TC), the cathode is only connected to the temperature compensation drive voltage (V _TC) ( 71), and anode terminal connected to the temperature compensation drive voltage (V _TC), and to the cathode end is connected to the Vcc driving voltage and a second diode array (72) for limiting the upper limit of the temperature compensation drive voltage (V _TC) .

The user interface unit 10 remotely controls the M-bit command signal, and the user interface unit 10 removes noise components included in the M-bit amplification command signal, A noise removing unit 11 for providing an output signal to the voltage generating unit 20 and a buffering unit 12 inserted between the noise removing unit 11 and the voltage generating unit 20 to buffer the voltage difference do.

The buffering means 12 is connected between the noise removing means 11 and the voltage generating portion 20 and includes M buffering resistors R ₁₁ to R _1M ).

The voltage generator 20 includes M input terminals for receiving the M bit output signals from the noise canceling means 11 of the user interface unit 10 and only one output terminal according to the bit combination of the M bit output signals and a decoder 21 provided with a 2 ^M of the output stage is active, the ^M 2 of the output stage are respectively connected one to each of a plurality of split resistors having different resistance values (R ₂₁ ~R _2N) and a plurality of the division resistance ( And a voltage dividing resistor R _DIV for applying a control voltage to the current generating unit 30 by dividing the temperature compensating driving voltage V _TC together with a dividing resistor connected to an outputting end of the current generating unit 30, R ₂₁ to R _2N .

The current generating unit 30 includes a buffer amplifier 31 receiving a control voltage from the voltage generating unit 20 and a buffer amplifier 31 connected between the buffer amplifier 31 and the temperature compensating driving voltage V _TC , A current generating resistor R _ref for generating a variable control current and a MOSFET serving as a current path means for providing the control current generated in the current generating resistor R _ref to the amplifier 40 (field effect transistor: Q ₁ ).

The temperature sensor 50 senses the internal temperature and the external temperature of the amplifier and outputs a temperature sensing signal of a displacement amount having a polarity opposite to the temperature coefficient of the amplifier amplification degree.

Wherein a temperature compensator 60 is a temperature for a voltage conversion resistor to convert the temperature detection signal to be outputted to the voltage value from the sensor (50) (R ₆₁₎ and the converted temperature into a voltage value by the resistor (R ₆₁₎ A buffering operational amplifier 61 for holding a sensing signal and filtering means C ₆₂ , C ₆₃ , R ₆₂ and R ₆₃ for removing a noise signal included in an output signal of the buffering operational amplifier 61. The capacitor C ₆₁ connected in parallel with the voltage conversion resistor R ₆₁ bypasses the high frequency noise component included in the temperature sensing signal.

The operation and effect of the present invention constituted as described above are as follows.

First, the user adjusts the amplification degree of the amplifier 40 by using a remote controller (not shown), and this remotely controlled M bit amplification degree command signal is input to the noise elimination means 11. The noise removing unit 11 may be implemented using a schmitt-trigger inverter and an RC circuit that remove noise included in the M-bit amplification command signal. The M-bit amplified signal command signal is input to the decoder 21 of the voltage generator 20 through the buffering resistors R ₁₁ to R _1M .

The voltage generator 20 generates a control voltage applied to the current generator 30. To this end, the decoder 21 combines two bits of the M-bit amplification command signal input to the M input terminals to activate one output terminal of the ^2M output terminals. That is, one output is active "low (low)" is one end of one of the divided ground resistance of split resistor (R ₂₁ ~R _2N) in accordance with a command signal amplification of the M bit. Here, applied to the splitting resistance (R ₂₁₎ is the assumption that the selection is grounded, the temperature compensation drive voltage (V _TC) is the voltage-dividing resistor (R _DIV) and the division resistance (R ₂₁₎ divided by a dividing resistance (R ₂₁₎ Is applied to the current generating section 30 as a control voltage.

Here, by dividing the resistors (R _2N ~R ₂₁₎ because each of all other reading the resistance value, the current generator 30 in accordance with the resistance value of the dividing resistor (R ₂₁ ~R _2N) that are selected by the decoder 21 The applied control voltage is changed. Also, the control current I _C input to the amplifier 40 is changed according to the control voltage, so that the amplification degree of the amplifier 40 is varied. That is, the amplification command signal inputted by the user determines the amplification degree of the amplifier 40 through the path as described above.

The current generator 30 generates a control current I _C that determines the amplification degree of the amplifier 40. That is, when the control voltage of the voltage generator 20 is applied to the non-inverting input terminal of the buffer amplifier 31, the inverting input terminal of the buffer amplifier 31, that is, the drain of the MOSFET Q ₁ The control voltage is applied. At this time, the control current I _C is determined as shown in Equation (1).

The thus obtained control current I _C is input to the amplifier 40 to determine the amplification degree.

When the amplifier 40 is heated for a long time or the external temperature rises, the amplification degree of the amplifier 40 is reduced even if the control current I _C of the same magnitude is input from the current generation unit 30, The amplification degree of the amplifier 40 is increased, which is compensated by the temperature compensating section 60. In this case,

To this end, the temperature sensor 50 outputs a temperature sensing signal I _D of displacement amount having a polarity opposite to the temperature coefficient of the amplification degree of the amplifier 40. That is, when the amplifier 40 is deteriorated and the amplification degree is changed by the amount of displacement? A, the temperature sensor 50 outputs the temperature sensing signal I _D having the displacement amount? T = -ΔA. This temperature sensing signal I _D is removed from the high frequency noise by the capacitor C61 and converted into a voltage value by the voltage converting resistor R61 and applied to the noninverting input terminal of the buffering operational amplifier 61. [ The temperature sensing voltage amplified by the buffering operational amplifier 61 is output as a temperature-compensated driving voltage (V _TC ) after noise is removed by filtering means (C ₆₂ , C ₆₃ , R ₆₂ , R ₆₃ ).

The temperature compensating driving voltage V _TC is applied to the voltage generating unit 20 and the current generating unit 30. The control current I _C according to the temperature compensating driving voltage V _TC is calculated as shown in Equation 2 do.

When the temperature of the amplifier 40 is decreased, the amplification degree of the amplifier 40 is increased. At this time, the temperature sensing signal I _D of the temperature sensor 50 is decreased, _TC ) decreases. When the temperature-compensated driving voltage V _TC decreases, the magnitude of the control current I _C input to the amplifier 40 decreases and the amplification degree decreases. As a result, the amplification degree of the amplifier 40, which has increased due to the low temperature, do.

In addition, as the temperature of the amplifier 40 increases, the amplification of the amplifier 40 decreases, at which time the temperature sensing signal I _D of the temperature sensor 50 increases and accordingly the temperature compensated driving voltage V _TC also increases . When the temperature compensating driving voltage V _TC increases, the magnitude of the control current I _C input to the amplifier 40 increases to increase the amplification degree. Thus, the amplification degree of the amplifier 40, Is corrected.

Here, if the temperature sensor 50 fails or the amplifier 40 is placed in an excessive temperature environment, the entire system becomes unstable due to excessive temperature compensation. That is, when the temperature of the amplifier 40 becomes too high or the temperature sensor 50 fails and the temperature sensing signal I _D abruptly increases, the temperature compensating driving voltage V _TC becomes abnormally large. In addition, when the temperature of the amplifier 40 suddenly becomes low or the temperature sensor 50 fails and the temperature sensing signal I _D suddenly decreases, the temperature compensation driving voltage V _TC becomes abnormally small.

When the temperature compensation drive voltage _VTC deviates from the temperature compensation control range due to an abnormal operation state as described above, the circuit protection unit 70 operates to maintain a minimum system operation.

More specifically, when the temperature sensor 50 observes an excessive temperature or when the temperature detection signal I _D becomes excessively large due to a failure, the temperature compensating driving voltage V _TC increases and the temperature compensating driving voltage (V _TC) and the difference voltage of Vcc drive voltage is greater than the conduction voltage of the second diode array 72, the second diode array 72 while the turn-on temperature compensation drive voltage (V _TC) is the upper limit value, that is Vcc drive Voltage and the conduction voltage of the second diode array 72 are maintained. That is, when the conduction voltage of the second diode array 72 is k⋅V _ac , The temperature-compensated driving voltage (V _TC ) is Vcc + k⋅V _ac .

On the other hand, when the amplifier 40 observes a cryogenic temperature or when the temperature sensor 50 fails and supplies a too low temperature sensing signal I _D , the temperature compensating driving voltage V _TC decreases and the Vcc driving voltage and greater than the conduction voltage of the temperature compensation drive voltage (V _TC), the voltage difference is the first diode array (71) of the first diode array 71 is turned on, temperature compensation drive voltage (V _TC), while on the lower limit, that is Vcc And is maintained at a difference voltage between the drive voltage and the conduction voltage of the first diode array 71. That is, when the conduction voltage of the first diode array 71 is k⋅V _ac , The temperature-compensated driving voltage (V _TC ) is Vcc - k⋅V _ac .

As described above, according to the present invention, when the amplification degree of the amplifier is varied according to the internal temperature or the external temperature of the amplifier, the temperature-compensating driving voltage is adjusted to adjust the magnitude of the control current for driving the amplifier, It is possible to compensate the amplification degree of the amplifier.

In addition, when the temperature compensation drive voltage is out of the temperature compensation control range due to malfunction of the temperature compensation of the amplifier, the temperature compensation drive voltage maintains the upper limit value or the lower limit value, so that the minimum operation of the circuit can be maintained.

Claims (8)

A voltage generating unit for generating a control voltage by dividing a temperature-compensated driving voltage according to the control signal input from the user interface unit; A current generator for generating a control current varying according to the control voltage and the temperature compensating drive voltage applied from the voltage generator and providing the control current to the amplifier; a temperature sensor for detecting the change in the external temperature and the internal temperature of the amplifier, A temperature sensing means for receiving a temperature sensing signal input from the temperature sensing means and compensating for an amplification degree variation of an amplifier which varies according to the temperature, the temperature sensing means for outputting a temperature sensing signal of a displacement amount having an opposite polarity to the temperature, A temperature compensating unit for outputting a voltage; And a circuit protection unit for limiting a lower limit value and an upper limit value of the temperature compensation drive voltage to be applied to the amplifier. When the amplification degree of the amplifier changes according to an internal temperature or an external temperature, a control current supplied to the amplifier varies, So that the amplification degree of the amplifier is always kept constant regardless of the temperature. The circuit protection device of claim 1, wherein the circuit protection unit includes: a first diode array having an anode terminal connected to a Vcc driving voltage and a cathode terminal connected to the temperature compensating driving voltage to limit a lower limit of the temperature compensating driving voltage; And a second diode array having an anode terminal connected to the temperature compensating driving voltage and a cathode terminal connected to the Vcc driving voltage to limit an upper limit value of the temperature compensating driving voltage. The apparatus of claim 1, wherein the amplification command signal is remotely controlled by M bits, and the user interface removes a noise component included in an M-bit amplification command signal input through a remote control, And a noise canceling means for providing noise to the amplifier. The control current generating circuit of claim 3, wherein the user interface unit further comprises a buffering unit inserted between the noise removing unit and the voltage generating unit to buffer the voltage difference. 5. The amplifier of claim 4, wherein the buffering means is M buffering resistors connected between the noise removing means and the voltage generating means and providing the path of the M-bit output signal output from the noise removing means. Control current generating circuit. The apparatus of claim 1, wherein the voltage generator comprises M input terminals and ^2M output terminals for receiving the M bit output signal from the noise removing means, A decoder configured to be active; A plurality of split resistors connected to the 2 ^M output terminals, respectively, and having different resistance values; And a voltage dividing resistor for dividing a temperature compensating driving voltage together with a dividing resistor connected to an output end of the plurality of dividing resistors and applying a control voltage to the current generating unit. The plasma display apparatus of claim 1, wherein the current generator comprises: a buffer amplifier receiving a control voltage from the voltage generator; A current generating resistor connected between the buffer amplifier and the temperature compensating driving voltage to generate a control current varying according to the control voltage; And current path means for providing the control current generated in the current generating resistor to an amplifier. The temperature sensor according to claim 1, wherein the temperature compensating unit comprises: current / voltage converting means for converting a temperature sensing signal output from the temperature sensing means into a voltage value; And a filtering means for removing a noise signal included in an output signal of the buffering operational amplifier and outputting a temperature compensating driving voltage.