Reference voltage generation circuit, power source device, liquid crystal display device

A reference voltage generation circuit of the disclosure includes a first amplifier circuit and a second amplifier circuit. The first amplifier circuit includes a first input stage including two npn transistors or two NMOS transistors having base terminals or gate terminals to which a variable voltage and a predetermined lower limit voltage are inputted. A first output stage includes a pnp transistor or a PMOS transistor having an emitter terminal or a source terminal connected to an output terminal of a reference voltage. A first amplifier stage controls the first output stage for equalizing the higher one of the variable voltage and the lower limit voltage with the reference voltage. The second amplifier circuit includes a second input stage including two npn transistors or two NMOS transistors having base terminals or gate terminals to which the reference voltage and a predetermined higher limit voltage are inputted, a second output stage includes a pnp transistor or a PMOS transistor having an emitter terminal or a source terminal connected to an output terminal for the reference voltage, and a second amplifier stage to control the second output stage for equalizing the reference voltage with the higher limit voltage.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of priority of Japanese patent application No. 2010-128413(filing date: Jun. 4, 2010), which is incorporated herein by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The disclosure relates to a reference voltage generation circuit to generate a reference voltage (i.e., an input variable voltage to which a higher limit value and a lower limit value are set) in response to receiving a variable voltage, and a power source device and a liquid crystal display device using the circuit.

2. Description of Related Art

FIG. 4is a circuit diagram showing a first conventional example of a reference voltage generation circuit. A reference voltage generation circuit70of the first conventional example receives a temperature detection voltage VT (i.e., a voltage signal, the voltage value of which fluctuates according to temperature fluctuation) from a temperature sensor60, and generates a reference voltage VREF by setting a higher limit voltage VH and a lower limit voltage VL to the temperature detection voltage VT (in reference toFIG. 3).

As a technique to realize the operation described above by using an analog signal, the reference voltage generation circuit70in accordance with the first conventional example includes a first amplifier circuit X which preferentially outputs a higher voltage between the temperature detection voltage VT and the lower limit voltage VL, and a second amplifier circuit Y which preferentially outputs a lower voltage as a reference voltage VREF between the output voltage VX provided from the first amplifier circuit X and the higher limit voltage VH.

As an input stage, the first amplifier circuit X is a construction which includes npn bipolar transistors X1and X2, to each base terminal of which the temperature detection voltage VT and the lower limit voltage VL are inputted (i.e., the first amplifier circuit X is kind of a npn-input-type amplifier). As an input stage, the second amplifier circuit Y is a construction which includes pnp bipolar transistors Y1and Y2, to each base terminal of which the output voltage VX and the higher limit voltage VH are inputted (i.e., the second amplifier circuit Y is kind of a pnp-input-type amplifier).

In addition, as an example of a technique related to the aforementioned conventional technique, Japanese patent publication No. 2009-232550 can be listed.

However, because the second amplifier circuit Y of pnp-input-type is used for the reference voltage generation circuit70of the first conventional example, at least a voltage value corresponding to the sum of the three voltage is required as a power source voltage to drive the input stage of the second amplifier circuit Y: the higher limit voltage VH applied to a base terminal of the transistor Y2, an ON threshold voltage Vf of the transistor Y2, and a drop voltage Vsat of the current source Y5(i.e., VH+Vf+Vsat≈VH+1V). Therefore, with respect to the reference voltage generation circuit70of the first conventional example, a problem arises because a minimum operation voltage (i.e., a lowest value of the power source voltage required to maintain a normal operation) cannot be lowered adequately.

As shown inFIG. 5, as a technique to generate the reference voltage VREF (i.e., the temperature detection voltage VT to which the higher limit voltage VH and a lower limit voltage VL are set), a combination of buffers91to93, comparators94to95, a logic circuit96and a selector97which operates by digital signal, can be proposed. However, such a combination can result in an increase in circuit size or cost, as well as noise occurring during switching of the selector, deterioration of transient characteristics remains problems in addition to the aforementioned problems.

SUMMARY OF THE INVENTION

Therefore, in view of the aforementioned problems identified by the inventor of this application, a purpose of the disclosure is to provide a reference voltage generation circuit which can lower a lower operation voltage, and to provide a power source device and a liquid crystal display device using the circuit.

According to one aspect of the disclosure, a reference voltage generation circuit of the disclosure includes a first amplifier circuit and a second amplifier circuit. The first amplifier circuit includes a first input stage including two npn transistors or two NMOS transistors. A variable voltage and a predetermined lower limit voltage are inputted to base terminals or gate terminals of the transistors. The first amplifier circuit includes a first output stage including a pnp transistor or a PMOS transistor, an emitter terminal or a source terminal of the first output stage transistor is connected to an output terminal of a reference voltage. The first amplifier circuit also includes a first amplifier stage to control the first output stage for equalizing the higher one of the variable voltage and the lower limit voltage with the reference voltage. The second amplifier circuit includes a second input stage including two npn transistors or two NMOS transistors. The reference voltage and a predetermined higher limit voltage are inputted to base terminals or gate terminals of these input stage transistors. The second amplifier circuit also has a second output stage including a pnp transistor or a PMOS transistor. An emitter terminal or a source terminal of the second output stage transistor is connected to an output terminal of the reference voltage. The second amplifier circuit further includes a second amplifier stage to control the second output stage for equalizing the reference voltage with the higher limit voltage.

Other features of the disclosure, elements, steps, advantages, and characteristics will be apparent from the following description and the accompanying drawings and the claims.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1is a block diagram showing a construction example of a liquid crystal display device in accordance with the disclosure. The liquid crystal display device1of the disclosure includes a power source IC10, a temperature sensor20, a gate driver30, a source driver40, and a liquid crystal display panel50(LCD[Liquid Crystal Display] panel50in the following description).

The power source IC10is a semiconductor device to generate an output voltage VOUT from an input voltage VIN, and to supply the output voltage VOUT to the gate driver30, including a reference voltage generation circuit11and a DC/DC converter12.

The reference voltage generation circuit11receives a temperature detection voltage VT (i.e., a voltage signal, the voltage value of which fluctuates in accord to a temperature fluctuation of the LCD panel50) from the temperature sensor20, and generates the reference voltage VREF (in reference toFIG. 3) to which a predetermined higher limit voltage VH and a lower limit voltage VL are set. The construction and operation of the reference voltage generation circuit11are described below in detail.

The DC/DC converter12generates an output voltage VOUT from the input voltage VIN in accord to the reference voltage VREF. In addition, as for the DC/DC converter12, if the required output voltage VOUT can be generated from the input voltage VIN, any circuit construction (e.g., a switching regulator, a series regulator, a charge pump circuit, and so on) can be adopted.

The temperature sensor20is provided around the LCD panel50, and generates the temperature detection voltage VT, the voltage value of which fluctuates according to a temperature fluctuation of the LCD panel50. The construction and operation of the temperature sensor20are explained below using a particular example.

The gate driver30operates by receiving the supplement of the output voltage VOUT from the power source IC10, and generates a gate drive signal for a TFT transistor (TFT[Thin Film Transistor]) provided to every cell of the LCD panel50according to a vertical synchronizing signal provided from a logic part (the logic part is not illustrated). A voltage value of the gate drive signal fluctuates according to an output voltage VOUT.

The source driver40generates a source drive signal for a TFT transistor provided to every cell of the LCD panel50according to an image signal provided from a logic part (the logic part is not illustrated).

The LCD panel50displays an arbitrary character or an image by receiving a gate drive signal and a source drive signal from the gate driver30and the source driver40, respectively.

As described above, with respect to a liquid crystal display device1in accordance with an example of the implementation, the power source IC10includes a function which performs variable control for voltage value of the output voltage VOUT provided to the gate driver30(i.e., Furthermore, a voltage value of the gate drive signal provided to the LCD panel50) according to an ambient temperature of the LCD panel50. In other words, the power source IC10includes a function for compensating temperature of the LCD panel50. This construction makes it possible to realize a panel characteristic (e.g., contrast and gamma curve) free from fluctuation of temperature, and to enhance visibility and color reproducibility of the LCD panel50.

FIG. 2is a circuit diagram showing a construction example of a reference voltage generation circuit11and a temperature sensor20. The reference voltage generation circuit11of the disclosure includes a first amplifier circuit A and a second amplifier circuit B. The first amplifier circuit A includes a npn bipolar transistors A1and A2, a pnp bipolar transistor A3, an operational amplifier A4, and current sources A5to A7. The second amplifier circuit B includes npn bipolar transistors B1and B2, a pnp bipolar transistor B3, an operational amplifier B4, and current sources B5and B6.

A collector terminal of the transistor A1is connected to a power source terminal. An emitter terminal of the transistor A1is connected to a ground terminal via the current source A5. A base terminal of the transistor A1is connected to an apply terminal of the temperature detection voltage VT. A collector terminal of the transistor A2is connected to a power source terminal. An emitter terminal of the transistor A2is connected to the ground terminal via the current source A6. A base terminal of the transistor A2is connected to a apply terminal of the lower limit voltage VL. A first non-inverting input terminal (+) of the operational amplifier A4is connected to an emitter terminal of the transistor A1. A second non-inverting input terminal (+) of the operational amplifier A4is connected to an emitter terminal of the transistor A2. An inverting terminal (−) of the operational amplifier A4is connected to an output terminal of the reference voltage VREF. An output terminal of the operational amplifier A4is connected to a base terminal of the transistor A3. An emitter terminal of the transistor A3is connected to an output terminal of the reference voltage VREF, and also connected to the power source terminal via a current source A7. A collector terminal of the transistor A3is connected to the ground terminal.

A collector terminal of the transistor B1is connected to the power source terminal. An emitter terminal of the transistor B1is connected to the ground terminal via the current source B5. A base terminal of the transistor B1is connected to an apply terminal of the higher limit voltage VH. A collector terminal of the transistor B2is connected to the power source terminal. An emitter terminal of the transistor B2is connected to the ground terminal via the current source B6. A base terminal of the transistor B2is connected to an output terminal of the reference voltage VREF. A non-inverting input terminal (+) of the operational amplifier B4is connected to an emitter terminal of the transistor B1. An inverting terminal (−) of the operational amplifier B4is connected to an emitter terminal of the transistor B2. An output terminal of the operational amplifier B4is connected to a base terminal of the transistor B3. An emitter terminal of the transistor B3is connected to an output terminal of the reference voltage VREF. A collector terminal of the transistor B3is connected to the ground terminal.

As for the first amplifier circuit A of the aforementioned construction, the first input stage is constructed with the transistors A1and A2, and the current sources A5and A6. The first output stage is constructed with the transistor A3and the current source A7. The first amplifier stage for controlling the first output stage (i.e., the transistor A3in detail) is constructed by the operational amplifier A4to equalize the higher one of the temperature detection voltage VT and the lower limit voltage VL with the reference voltage VREF.

With respect to the second amplifier circuit B constructed with the aforementioned construction, the second input stage is constructed with transistors B1and B2, and the current sources B5to B6. The second output stage is constructed with the transistor B3. The second amplifier stage for controlling the second output stage (i.e., the transistor B3in detail) to equalize the reference voltage VREF with the higher limit voltage VH is constructed with the operational amplifier B4.

The temperature sensor20in accordance with the implementation includes the resistors21and22, and the thermistor23. The resistor21is connected between the power source terminal and an output terminal of the temperature detection voltage VT. The resistor22is connected between the ground terminal and an output terminal of the temperature detection voltage VT. The thermistor23is connected to the resistor21in parallel.

As the thermistor23, so called a NTC (Negative Temperature Coefficient) thermistor is used, the temperature coefficient of which is negative (i.e., the resistance value is lowered as the ambient temperature around the LCD panel50increases). Therefore, the higher an ambient temperature around the LCD panel50becomes, the lower the synthesized resistance value of the resistor21and the thermistor23becomes smaller. As the ambient temperature around the LCD panel50becomes higher, the higher the voltage value of the temperature detection voltage VT becomes, as shown inFIG. 3.

A detailed explanation is described below about an operation of the reference voltage generation circuit11according to the abovementioned construction.

If VL is greater than or equal to VT, in the first amplifier circuit A, a feedback control is performed for the transistor A3by the operational amplifier A4, to equalize the lower limit voltage VL, which is higher than the temperature detection voltage VT, with the reference voltage VREF. Thus, the first amplifier circuit A preferentially outputs the lower limit voltage VL than the temperature detection voltage VT. On the other hand, in the second amplifier circuit B, a feedback control for the transistor B3by the operational amplifier B4is performed, to equalize the reference voltage VREF with the higher limit voltage VH. However, only the capability to extract a current from the output terminal of the reference voltage VREF is provided to the transistor B3(i.e., a capability to lower a voltage value of the reference voltage VREF not to surpass the higher limit voltage VH). Therefore, if the reference voltage VREF is lower than the higher limit voltage VH, the second amplifier circuit B transitions to a state which does not function at all (i.e., in detail, an output signal of the operational amplifier B4over swings to a high level, and the transistor B3is completely turned OFF). According to the aforementioned operation, the reference voltage VREF does not lower the lower limit voltage VL and is kept at a lower limit voltage VL.

If VH is greater than VT, and VT is greater than VL, in the first amplifier circuit A, a feedback control is performed for the transistor A3by the operational amplifier A4, to equalize the temperature detection voltage VT, which is higher than the lower limit voltage VL, with the reference voltage VREF. Thus, the first amplifier circuit A preferentially outputs a temperature detection voltage VT than the lower limit voltage VL. On the other hand, in the second amplifier circuit B, a feedback control for the transistor B3by the operational amplifier B4is performed, to equalize the reference voltage VREF with the higher limit voltage VH. However, only a capability to extract a current from the output terminal of the reference voltage VREF is provided to the transistor B3, if the reference voltage VREF is lower than the higher limit voltage VH, the second amplifier circuit B transitions to a state which does not function at all. According to the aforementioned operation, a voltage value of the reference voltage VREF fluctuates in synchronization with the temperature detection voltage VT.

IF VT is greater than or equal to VH, in the first amplifier circuit A, a feedback control is performed for the transistor A3by the operational amplifier A4, to equalize the temperature detection voltage VT, which is higher than the lower limit voltage VL, with the reference voltage VREF. Thus, the first amplifier circuit A preferentially outputs the temperature detection voltage VT than the lower limit voltage VL. On the other hand, in the second amplifier circuit B, a feedback control for the transistor B3by the operational amplifier B4is performed, to equalize the reference voltage VREF with the higher limit voltage VH. Thus, in the second amplifier circuit B, a current is extracted from the output terminal of the reference voltage VREF via the transistor B3, the reference voltage VREF is lowered to the higher limit voltage VH. At same time, as mentioned above, in the first amplifier circuit A, a feedback control is performed for the transistor A3by the operational amplifier A4, to equalize the temperature detection voltage VT with the reference voltage VREF. However, only a capability to extract a current from the output terminal of the reference voltage VREF is provided to the transistor A3. Therefore, if the reference voltage VREF is clamped to a higher limit voltage VH lower than the temperature detection voltage VT, the first amplifier circuit A transitions to a state which does not function at all (i.e., in detail, an output signal of the operational amplifier A4over swings to a high level and the transistor A3is completely turned OFF). According to the aforementioned operation, a voltage value of the reference voltage VREF is kept at the higher limit voltage VH not to surpass the higher limit voltage VH.

As described above, the reference voltage generation circuit11in accordance with the implementation differs from the conventional construction using the npn-input-type first amplifier circuit X and the pnp-input-type second amplifier circuit Y (in reference toFIG. 4), by using the first amplifier circuit A and the second amplifier circuit B both which include npn-input stage and pnp-output stage, and only have capability of extracting a current, then each output of the amplifier circuits A and B is shorted, and the reference voltage VREF can be generated. Based on this construction, without using the pnp-input-type second amplifier circuit Y (i.e., the pnp transistor Y2, the higher limit voltage VH is inputted to a base terminal of the transistor Y2), the function of clamping the reference voltage VREF to the higher limit voltage VH (i.e., a function to preferentially output the lower voltage between the two inputted voltages) can be realized. Therefore, the minimum operation voltage of the reference voltage generation circuit11can be lowered, which makes it possible to contribute to a reduction in energy consumption of the power source IC10and the liquid crystal display device1using the circuit.

With respect to the aforementioned implementation, as transistors constructing the first amplifier circuit A and the second amplifier circuit B, an example is described in reference a construction which uses bipolar transistors A1to A3and B1to B3. The construction of the disclosure is not restricted to the example, on behalf of a bipolar transistor, a MOS[Metal Oxide Semiconductor] FET [Filed Effect transistor] can be used, for example. In that case, equivalent replacement can be realized by replacing a base terminal, an emitter terminal, and a collector terminal of the bipolar transistor to a gate terminal, a source terminal, and a drain terminal of the MOS FET, respectively.

In the above mentioned implementation, the example is described as applying the reference voltage generation circuit11(i.e., the generation circuit11generates the reference voltage VREF by setting the higher limit voltage VH and the lower limit voltage to the temperature detection voltage VT) to the disclosure. However, application of the disclosure is not restricted to the example. The disclosure can be applied flexibly to a general reference voltage generation circuit which generates a reference voltage by setting a higher limit value and a lower limit value to a variable voltage.

As for the reference voltage generation circuit disclosed in the specification, the minimum operation voltage can be lowered, which makes it possible to contribute to a reduction in energy consumption of the power source device and the liquid crystal display device using the circuit.

A technical characteristic disclosed in the specification can possibly be used as a technique to lower a minimum operation voltage of the power source device including a temperature compensation function for the liquid crystal display panel.

In the above description, best mode implementations of the disclosure have been described. Nevertheless, various modifications can be made, and it is evident to a person of ordinary skill that other implementations can be included apart from the aforementioned constructions. Accordingly, any other implementations are within the scope of the claims without departing from the spirit and scope of the disclosure.

List of Reference Numerals

1liquid crystal display device

10power source IC

11reference voltage generation circuit

A first amplifier circuit

A3pnp type bipolar transistor

B second amplifier circuit

B3pnp type bipolar transistor