JP4453475B2 - Level conversion circuit, power supply voltage generation circuit, and display device - Google Patents

Description

  The present invention relates to a level conversion circuit (level shift circuit), a power supply voltage generation circuit, and a display device, and more particularly to a level conversion circuit formed on an insulating substrate, a power supply voltage generation circuit using the level conversion circuit, and the power supply voltage. The present invention relates to a display device equipped with a generation circuit.

  Conventionally, a current mirror type level conversion circuit configured using a current mirror circuit is known as a level conversion circuit (see, for example, Patent Document 1).

  FIG. 15 is a circuit diagram showing an example of a configuration of a current mirror type level conversion circuit according to a conventional example. As illustrated in FIG. 15, the current mirror type level conversion circuit 100 includes a circuit operation control unit 101, two bias shift units 102 and 103, a level shift unit 104, and an output unit 105.

  The circuit operation control unit 101 includes two Pch MOS transistors (hereinafter abbreviated as “PMOS transistors”) p101 and p102 and an Nch MOS transistor (hereinafter abbreviated as “NMOS transistor”) n101. The PMOS transistor p101 and the NMOS transistor n101 have a power supply line to which a positive power supply potential Vdd is applied (hereinafter referred to as “Vdd line”) and a power supply line to which a negative power supply potential Vss is applied (hereinafter referred to as “Vss line”). Are connected in series, and the gates and drains are connected in common.

  A circuit operation control signal xstb is externally supplied to the gates of the PMOS transistor p101 and the NMOS transistor n101. The circuit operation control signal xstb is always at a low potential when the circuit is in a standby state (when not driven), and is always at a high potential when the circuit is driven. The PMOS transistor p102 has a source connected to the Vdd line and a gate connected to the gates of the PMOS transistor p101 and the NMOS transistor n101.

  The bias shift unit 102 includes two PMOS transistors p103 and p104 and one NMOS transistor n102. The PMOS transistor p103 and the NMOS transistor n102 are connected in series between the Vdd line and the Vss line, the gates are connected in common, and are further connected to the drains of the PMOS transistor p101 and the NMOS transistor n101, and the drains are connected to each other. Commonly connected. The PMOS transistor p104 is connected in parallel to the NMOS transistor n102, and a clock CK is supplied to the gate. In the bias shift unit 102, an operation of shifting the DC bias of the clock CK is performed.

  The bias shift unit 103 includes two PMOS transistors p105 and p106 and one NMOS transistor n103. The PMOS transistor p103 and the NMOS transistor n102 are connected in series between the Vdd line and the Vss line, and the gates and the drains are connected in common. The PMOS transistor p106 is connected in parallel to the NMOS transistor n103, and a clock xCK having a phase opposite to that of the clock CK is applied to the gate. In the bias shift unit 103, an operation of shifting the DC bias of the reverse phase clock xCK is performed.

  The level shift unit 104 includes two PMOS transistors p107 and p108 and two NMOS transistors n104 and n105. The two PMOS transistors p107 and p108 have their sources connected to the Vdd line and their gates connected in common, and the gate and drain of the PMOS transistor p107 are connected to form a current mirror circuit. ing. The drain (gate) of the PMOS transistor p107 is connected to the drain of the PMOS transistor p102.

  The NMOS transistor n104 has a drain connected to the drain (gate) of the PMOS transistor p107, a gate connected to each drain of the PMOS transistor p103 and the NMOS transistor n102, and a negative phase clock xCK applied to the source. The NMOS transistor n105 has a drain connected to the drain of the PMOS transistor p108, a gate connected to the drains of the PMOS transistor p105 and the NMOS transistor n103, and a clock CK applied to the source.

  As is apparent from the above configuration, the level shift unit 104 has a circuit configuration of a source input type current mirror amplifier that uses the negative phase clock xCK and the normal phase clock CK as the source inputs of the NMOS transistors n104 and n105.

  The output unit 105 includes an NMOS transistor n106 having a drain connected to each drain of the PMOS transistor p108 and the NMOS transistor n105, a source connected to the Vss line, and a gate connected to each gate of the PMOS transistor p105 and the NMOS transistor n103. .

JP 2003-347926 A

  In the current mirror type level conversion circuit 100 according to the conventional example having the above configuration, after the DC bias of the clocks CK and xCK is shifted by the bias shift units 102 and 103, the level shift unit 104 finally converts the clocks CK and xCK to Vss. Since it is configured to level shift (level conversion) to a clock having an amplitude of −Vdd, a leak current (through current) always flows in a portion indicated by a dotted arrow in the figure. This is a cause of increasing the power consumption of the level conversion circuit 100.

  Further, the current mirror type level conversion circuit 100 has a problem that the characteristics of the pair of PMOS transistors p107 and p108 constituting the current mirror circuit need to be the same, so that it is vulnerable to variations in transistor characteristics.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object of the present invention is to provide a level conversion circuit that can reduce power consumption and is resistant to variations in transistor characteristics, and power supply voltage generation using the level conversion circuit. It is an object of the present invention to provide a display device including a circuit and the power supply voltage generation circuit.

  The level conversion circuit according to the present invention includes a first terminal and a second transistor of opposite conductivity type connected in series between a first power supply potential and a second power supply potential, and a clock terminal to which a clock signal is input. And the first switch means which is connected between the clock terminal and the gate of the first transistor and which is turned on when the circuit operation control signal is in the active state, the second power supply potential, and the second Connected between the clock terminal and the gate of the second transistor. The second switch means is connected between the clock terminal and the gate of the second transistor. And a capacitive element.

  In the level conversion circuit having the above configuration, when the circuit operation control signal is in the active state, the first switch means is turned on, so that the clock is passed from the clock terminal to the gate of the first transistor through the first switch means. At the same time as the signal is applied, the second switch means is turned off, so that the supply of the second power supply potential to the gate of the second transistor is cut off, and the gate of the second transistor is in the floating state. At the same time, a clock signal is transmitted to the gate of the second transistor by coupling using a capacitive element.

  At this time, the clock signals applied to the gates of the first and second transistors have the same phase, but the high-level potential of the clock signal applied to the gate of the second transistor becomes the second power supply potential. The potential on the high level side of the clock signal applied to the gate of the first transistor is relatively shifted. The amplitude of the clock signal is larger than the threshold value Vth of the first and second transistors. As a result, the first and second transistors are surely turned off from the relationship of the gate potential at the timing to be turned off. Therefore, in the complementary circuit composed of the first and second transistors, leakage when these transistors are off can be reliably prevented.

  According to the present invention, it is possible to reliably prevent leakage at the time of off-state, so that it is possible to reduce power consumption and to provide a level conversion circuit that is resistant to variations in transistor characteristics because it employs a circuit configuration that does not use a current mirror circuit. .

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

[First Embodiment]
FIG. 1 is a circuit diagram showing a circuit configuration of a level conversion circuit according to the first embodiment of the present invention. The level conversion circuit 10 according to the present embodiment uses the first power supply potential Vss and the second power supply potential Vdd as the operation power supply potential, and uses a clock signal CK having a first amplitude, for example, 0 [V] -3 [V]. Is operated to perform level conversion (level shift) to a second amplitude, specifically, a clock signal of Vss-Vdd (for example, 0 [V] -8 [V]).

  As shown in FIG. 1, the level conversion circuit 10 according to the present embodiment includes a complementary circuit 11, an inverter 12, first to third switch circuits 13 to 15, a unidirectional circuit 16, and a capacitive element C. It has become.

  The complementary circuit 11 includes first and second transistors of opposite conductivity types connected in series between a power supply potential Vss and a power supply potential Vdd, that is, an NMOS transistor n11 and a PMOS transistor p11. The drains of the NMOS transistor n11 and the PMOS transistor p11 are connected to the circuit output terminal 17.

  The inverter 12 is connected in series between the power supply potential Vss and the power supply potential Vdd, and has a CMOS inverter configuration including an NMOS transistor n12 and a PMOS transistor p12 in which gates and drains are connected in common. The gates of the NMOS transistor n12 and the PMOS transistor p12 are connected to a control terminal 18 to which a circuit operation control signal xstb is given from the outside.

  The circuit operation control signal xstb is always at the power supply potential Vss (hereinafter referred to as “Low potential”) when the circuit is in a standby state (when not driven), and always at the power supply potential Vdd (hereinafter referred to as “High potential”) when the circuit is driven. Signal).

  The first switch circuit 13 includes a CMOS switch including an NMOS transistor n13 and a PMOS transistor p13 connected in parallel to each other. For example, a clock pulse CK having an amplitude of 0 [V] -3 [V] is applied from the outside. The input terminal is connected to the clock terminal 19 and the output terminal is connected to the gate of the NMOS transistor n11.

  The gate of the NMOS transistor n13 is at the input terminal of the inverter 12 (each gate of the NMOS transistor n12 and the PMOS transistor p12), and the gate of the PMOS transistor p13 is the output terminal of the inverter 12 (each drain of the NMOS transistor n12 and the PMOS transistor p12). Are connected to each. As a result, the circuit operation control signal xstb is given to the gate of the NMOS transistor n13, and a signal having a phase opposite to that of the circuit operation control signal xstb is given to the gate of the PMOS transistor p13.

  Here, a CMOS switch is used as the first switch circuit 13. However, if the high potential of the clock pulse CK is low enough not to worry about the threshold value Vth of the transistor with respect to the power supply potential Vdd, NMOS is used. A single switch can provide a sufficient margin. Therefore, in that case, an NMOS single switch can be used as the first switch circuit 13. When an NMOS single switch is used, the inverter 12 can be omitted because it is not necessary to generate a signal having a phase opposite to that of the circuit operation control signal xstb.

  The second switch circuit 14 is connected between the power supply potential Vdd and the gate of the PMOS transistor p11, and is configured by a PMOS transistor p14 that receives the circuit operation control signal xstb as a gate input. The second switch circuit 14 is turned off when the circuit operation control signal xstb is in an active state (High potential), thereby bringing the gate of the PMOS transistor p11 into a floating state.

  The third switch circuit 15 is connected between the power supply potential Vdd and the gate of the NMOS transistor n11, and is configured by a PMOS transistor p15 having the circuit operation control signal xstb as a gate input. The third switch circuit 15 is turned off when the circuit operation control signal xstb is in an active state, thereby electrically disconnecting the gate of the NMOS transistor n11 and the power supply potential Vdd.

  The unidirectional circuit 16 includes a diode connection, that is, an NMOS transistor n14 whose gate and drain are commonly connected, and a diode-connected PMOS transistor p16, and is connected between the gate of the PMOS transistor p11 and the power supply potential Vdd. Has been. The unidirectional circuit 16 is activated when the potential of the node B, that is, the gate of the PMOS transistor p11 is equal to or higher than the power supply potential Vdd, so that the potential of the node B becomes the power supply potential Vdd. to correct.

  However, even if the potential correction of the node B is performed by the unidirectional circuit 16, the potential of the node B actually decreases only to a potential obtained by adding the threshold value Vth of the MOS transistors n14 and p16 to the power supply potential Vdd.

  The capacitive element C is connected between the clock terminal 19 and the gate of the NMOS transistor n11. As a result, the clock pulse CK is transmitted to the gate of the PMOS transistor p11 by the coupling by the capacitive element C.

  Next, the circuit operation of the level conversion circuit 10 according to the first embodiment having the above configuration will be described with reference to timing charts of FIGS.

  First, a basic circuit operation of the level conversion circuit 10 when the circuit operation control signal xstb is in an active state, that is, High (power supply potential Vdd) will be described with reference to a timing chart of FIG.

  When the circuit operation control signal xstb becomes active, the first switch circuit 13 is turned on, and the second and third switch circuits 14 and 15 are turned off. When the first switch circuit 13 is turned on, the clock pulse CK is supplied from the clock terminal 19 to the gate of the NMOS transistor n11 through the first switch circuit 13.

  At the same time, when the second and third switch circuits 14 and 15 are turned off, the supply of the power supply potential Vdd to the gates of the PMOS transistor p11 and the NMOS transistor n11 is cut off, and the gate of the PMOS transistor p11 is in a floating state. It becomes. As a result, the clock pulse CK is transmitted from the clock terminal 19 to the gate of the PMOS transistor p11 by the coupling by the capacitive element C.

  At this time, the clock pulse CK supplied to the gates of the PMOS transistor p11 and the NMOS transistor n11 has the same phase, but the High-side potential of the clock pulse CK supplied to the gate of the PMOS transistor p11 becomes the power supply potential Vdd. As a result, the potential VB of the node B, that is, the gate potential of the PMOS transistor p11 becomes a value obtained by relatively shifting the potential VA of the node A, that is, the gate potential of the NMOS transistor n11.

  The amplitude of the clock pulse CK is larger than the threshold value Vth of the PMOS transistor p11 and the NMOS transistor n11. Thereby, the PMOS transistor p11 and the NMOS transistor n11 are surely turned off from the relationship between the potentials VA and VB of the nodes A and B at the timing to be turned off. Accordingly, in the complementary circuit 11 composed of the PMOS transistor p11 and the NMOS transistor n11, the clock pulse CK is level-converted into a clock pulse out having an amplitude of Vss-Vdd while reliably preventing leakage when the MOS transistors p11 and n11 are turned off. be able to.

  FIG. 3 is a timing chart showing the recommended timing of the circuit operation control signal xstb with respect to the clock pulse CK. As shown in this timing chart, the timing of the circuit operation control signal xstb is changed so that the circuit operation control signal xstb transitions from the inactive state to the active state when the clock pulse CK is High, that is, rises from Low to High. It is preferable to set. By performing such timing setting, the second switch circuit 14 is in the on state immediately before the circuit operation control signal xstb rises to high, and thus the potential VB of the node B becomes the power supply potential Vdd. From the start of driving, the potential VB of the node B behaves as intended.

  FIG. 4 is a timing chart showing the timing relationship when the circuit operation control signal xstb rises to High while the clock pulse CK is Low. The circuit operation control signal xstb rises to high level when the clock pulse CK is low, and the potential VB of the node B is changed from Vp + Vin when the high potential of the clock pulse CK is Vin. Will start.

  In this case, the potential VB of the node B is corrected to the power supply potential Vdd by the unidirectional circuit 16 that operates when the potential VB of the node B becomes equal to or higher than the power supply potential Vdd. However, as described above, the potential of the node B actually decreases only to the potential obtained by adding the threshold value Vth of the MOS transistors n14 and p16 to the power supply potential Vdd.

  As is clear from the above, there is no problem in the circuit operation even in the timing relationship of FIG. 4, but when considering the time until the circuit operation is guaranteed or more stable operation, the timing relationship of FIG. It can be said that the timing relationship in which the circuit operation control signal xstb rises to high while the clock pulse CK is high is preferable.

  As described above, the clock pulse CK having the first amplitude (for example, 0 [V] -3 [V]) is leveled to the clock pulse out having the second amplitude (for example, 0 [V] -8 [V]). In the level conversion circuit 10 for conversion, a complementary circuit 11 comprising an NMOS transistor n11 and a PMOS transistor p11 is a basic circuit, and a clock pulse CK is applied to the gate of the NMOS transistor n11 during circuit operation, while the gate of the PMOS transistor p11 is applied to the gate. By applying a clock pulse in which the clock pulse CK is relatively shifted to the power supply potential Vdd side by coupling by the capacitive element C, the NMOS transistor n11 and the PMOS transistor p11 are surely turned off at the timing to be turned off. Leakage current in the complementary circuit 11 It will not be.

  As described above, the leakage current does not flow in the level conversion circuit 10, so that the power consumption of the level conversion circuit 10 can be reduced. Further, since the complementary circuit 11 composed of a reverse conductivity type transistor is used as a basic circuit, transistor characteristics (threshold Vth and drain-source current are compared with the conventional level conversion circuit using a current mirror circuit as a basic circuit). It is possible to provide a level conversion circuit that is resistant to variations in Ids and the like. In addition, two clock signals CK and a circuit operation control signal Xstb are required as input clock signals, which can be reduced as compared with the conventional level conversion circuit that requires clock pulses CK and xCK having opposite phases.

[Second Embodiment]
FIG. 5 is a circuit diagram showing a circuit configuration of a level conversion circuit according to the second embodiment of the present invention. In FIG. 5, the same parts as those in FIG.

  As shown in FIG. 5, the level conversion circuit 20 according to the present embodiment includes components of the level conversion circuit 10 according to the first embodiment, that is, a complementary circuit 11, an inverter 12, and first to third switch circuits 13. In addition to the unidirectional circuit 16 and the capacitive element C, the reset circuit 21 is included.

  The reset circuit 21 is connected between the power supply potential Vdd and the gate of the PMOS transistor p11, and includes a PMOS transistor p17 that receives a reset pulse rst supplied from the outside to the reset terminal 22 as a gate input. The reset pulse rst is a pulse signal that goes Low when the clock pulse CK is High. The reset circuit 21 is turned on when the reset pulse rst is Low, thereby supplying the power supply potential Vdd to the gate of the PMOS transistor p11.

  Next, the circuit operation of the level conversion circuit 20 according to the second embodiment having the above configuration will be described with reference to the timing chart of FIG.

  First, the timing relationship of the reset pulse rst is set so that the duty of the reset pulse rst is shorter than that of the High period, and the Low period is within the High period of the clock pulse CK. Here, the low period of the reset pulse rst may be a time sufficient to charge the potential VB of the node B to the power supply potential Vdd.

  As can be seen from the timing chart of FIG. 2, the potential VB of the node B should be logically the power supply potential Vdd. However, in practice, as described above, the potential VB of the node B slightly deviates from the power supply potential Vdd. A reset circuit 21 is provided to correct a slight deviation from the power supply potential Vdd.

  In this reset circuit 21, since the PMOS transistor p17 is turned on in response to the reset pulse rst which becomes Low when the clock pulse CK is High, the power supply potential Vdd is changed to the node B (every time the clock pulse CK becomes High. To the gate of the PMOS transistor p11.

  As a result, the potential VB of the node B is surely set to the power supply potential Vdd during the High period of the clock pulse CK. That is, the reset circuit 21 performs the operation of determining the potential VB of the node B to the power supply potential Vdd periodically in this example for each cycle of the clock pulse CK, so that the circuit operation of the level conversion circuit 20 is ensured. To be done.

  The fact that the circuit operation is reliably performed will be described more specifically below. During the circuit operation period in which the circuit operation control signal xstb is High, the node B is in a floating state because the PMOS transistor p14 is turned off. As described above, the potential VB of the node B has a parasitic capacitance and the like. Therefore, it is necessary to perform control while keeping the potential VB floating. When the potential VB becomes higher than the power supply potential Vdd, the potential VB of the node B is actually corrected to the potential of Vdd + Vth by the action of the unidirectional circuit 16 so that the potential VB of the node B becomes the power supply potential Vdd.

  However, the unidirectional circuit 16 is a circuit that operates only when the potential VB of the node B becomes higher than the power supply potential Vdd. Accordingly, when the potential VB of the node B becomes lower than the power supply potential Vdd, the potential VB of the node B becomes lower than the power supply potential Vdd unless the circuit operation control signal xstb is once returned to Low and then set to High again. If the state continues and the potential VB is too low, the circuit operation cannot be continued.

  On the other hand, according to the level conversion circuit 20 according to the second embodiment, the reset circuit 21 periodically determines the potential VB of the node B that is in a floating state during the circuit operation period as the power supply potential Vdd. As a result, it is possible to prevent the potential VB from being excessively lowered, so that the circuit operation can be reliably performed.

  The level conversion circuits 10 and 20 according to the first and second embodiments are widely used as level conversion circuits for level conversion (level shift) of the clock pulse CK having the first amplitude to the clock pulse out having the second amplitude. For example, it can be used for a power supply voltage generation circuit that performs circuit operation based on a clock pulse. Hereinafter, application examples in which the level conversion circuits 10 and 20 according to the first and second embodiments are used in the power supply voltage generation circuit will be described.

(Application 1)
FIG. 7 is a block diagram showing a configuration of a power supply voltage generation circuit according to Application Example 1 of the present invention. As illustrated in FIG. 7, the power supply voltage generation circuit 30 according to the first application example includes a level shift unit (LSa) 31, a buffer unit (BUFa) 32, and a negative power supply generation unit (GENa) 33. . As the level shift unit 31, the level conversion circuit 10 according to the first embodiment described above or the level conversion circuit 20 according to the second embodiment is used.

  FIG. 8 is a block diagram illustrating an example of the configuration of the buffer unit 32. As shown in FIG. 8, the buffer unit 32 according to this example includes three inverter circuits 321, 322, and 323 connected in cascade. The three inverter circuits 321, 322, and 323 are configured such that the transistor size gradually increases from the input-side inverter circuit 321 to the output-side inverter circuit 323 in order to ensure the drive capability of the subsequent stage.

  As the inverter circuits 321, 322 and 323, for example, as shown in FIG. 9, a CMOS inverter connected in series between the power supply potential Vdd and the power supply potential Vss and having the gates and drains connected in common is used. It is done. However, the present invention is not limited to a CMOS inverter.

  FIG. 10 is a circuit diagram showing an example of the configuration of the negative power supply generation unit 33. As shown in FIG. 10, the negative power supply generation unit 33 according to this example has a configuration including two capacitors CA1 and CA2, two clamp circuits 331 and 332, and a sampling circuit 333. In the negative power source generation unit 33, the clock pulse out having the amplitude of Vss−Vdd converted in level by the level shift unit 31 passes through the buffer unit 32 and becomes clock pulses xin and in of opposite phases to the clock terminal 334. , 335.

  The two capacitors CA1 and CA2 function to cut the direct current component of the clock pulses xin and in. The clamp circuit 331 includes a PMOS transistor p22 that is connected between the output terminal of the capacitor CA1 and the power supply potential Vss, and has a gate connected to the output terminal of the capacitor CA2. The output level of the capacitor CA1 is set to the power supply potential Vss. Clamp to The clamp circuit 332 is connected between the output terminal of the capacitor CA2 and the power supply potential Vss, and includes a PMOS transistor p23 whose gate is connected to the output terminal of the capacitor CA1. The output level of the capacitor CA2 is set to the power supply potential Vss. Clamp to

  The sampling circuit 333 is configured by an NMOS transistor n22 that is connected between the output terminal of the capacitor CA1 and the circuit output terminal 336, and whose gate is connected to the output terminal of the capacitor CA2, and serves as a clamp output of the clamp circuit 332. Based on this, the clamp output of the clamp circuit 331 is sampled. The negative power supply voltage −Vdd is output from the circuit output terminal 336 by the action of the clamp circuits 331 and 332 and the sampling circuit 333.

  As described above, in the power supply voltage generation circuit 30 having the level shift unit 31, the buffer unit 32, and the negative power supply generation unit 33, the level conversion circuits 10 and 20 according to the first and second embodiments described above as the level shift unit 31. By using this, the level conversion circuits 10 and 20 can prevent the leakage current, thereby reducing the power consumption. Therefore, the power consumption of the power supply voltage generation circuit 30 can be reduced.

(Application example 2)
FIG. 11 is a block diagram showing a configuration of a power supply voltage generating circuit according to Application Example 2 of the present invention. In FIG. 11, the same parts as those in FIGS.

  In the power supply voltage generation circuit 40 according to the second application example, it is assumed that the level conversion circuit 20 according to the second embodiment is used as the level shift unit 31. The level conversion circuit 20 according to the second embodiment has a configuration including a reset circuit 21 that periodically determines the potential VB of the node B that is in a floating state during the circuit operation period to the power supply potential Vdd. Therefore, a reset pulse rst for controlling the reset circuit 21 is necessary.

  The power supply voltage generation circuit 40 according to the second application example is characterized in that the reset pulse rst is generated inside the power supply voltage generation circuit 40 by using the delay in the buffer unit 30. Specifically, the output x1 of the first-stage inverter 321 and the output x2 of the second-stage inverter 322 of the buffer unit 32 are taken out, and these outputs x1 and x2 are used as two inputs of the NAND circuit 34. A Low active reset pulse rst is generated as an output of the NAND circuit 34.

  FIG. 12 is a circuit diagram showing an example of the configuration of the NAND circuit 34. As shown in FIG. 12, in the NAND circuit 34 according to this example, gates are connected to circuit input terminals 341 and 342, and an NMOS transistor n23 connected in series between the circuit output terminal 343 and the power supply potential Vss. , N24, and PMOS transistors p24, p25 connected to each other in parallel between the power supply potential Vdd and the circuit output terminal 343. However, this circuit configuration is only an example, and the present invention is not limited to this.

  FIG. 13 is a timing chart showing a timing relationship for generating the reset pulse rst based on the outputs x1 and x2 of the buffer unit 32. As is apparent from this timing chart, the delay in the buffer unit 30 is used to perform the NAND operation on the output x1 of the first-stage inverter 321 and the output x2 of the second-stage inverter 322, so that the power supply voltage A low active reset pulse rst can be generated in the generation circuit 40.

  When a larger delay is required in the buffer unit 32, a method of increasing the number of inverter stages in the buffer unit 32 (however, an odd number) or a method of setting a circuit constant that causes a delay is adopted. Just do it.

  As described above, in the power supply voltage generation circuit 40 using the level conversion circuit 20 according to the second embodiment as the level shift unit 31, a low active is generated inside the power supply voltage generation circuit 40 using the delay in the buffer unit 30. By generating the reset pulse rst, it is not necessary to input the reset pulse rst from the outside, so that terminals for taking in the reset pulse rst can be reduced.

  In the application examples 1 and 2 described above, the case where the power supply voltage generation circuits 30 and 40 are negative power supply voltage generation circuits having the negative power supply section 33 has been described as an example. The same applies to the case of a circuit.

  The power supply voltage generation circuits 30 and 40 according to the applications 1 and 2 can be widely used as a power supply voltage generation circuit that performs circuit operation based on a clock pulse. As an example, pixels including electro-optical elements are arranged in a matrix of 2 In a display device integrated with a driving circuit in which a peripheral driving circuit for driving a pixel array unit arranged in a dimension is formed on the same substrate as the pixel array unit, it can be used as a part of the peripheral driving circuit.

(Application example)
FIG. 14 is a block diagram showing an example of the configuration of a display device according to an application example of the present invention. Here, an active matrix liquid crystal display device using a liquid crystal cell as an electro-optic element of a pixel will be described as an example of the display device.

  As shown in FIG. 14, an active matrix liquid crystal display device 50 according to this application example includes a pixel array unit 51, a vertical driver 52, a horizontal driver 53, a power supply voltage generation circuit 54, and the like. 53 and a peripheral drive circuit such as a power supply voltage generation circuit 54 are formed on the same liquid crystal panel 58 as the pixel array unit 51. The liquid crystal panel 58 has a configuration in which two insulating substrates, for example, glass substrates are arranged to face each other with a certain gap, and a liquid crystal material is sealed in the gap.

  In the pixel array unit 51, the pixels 60 are two-dimensionally arranged in m rows and n columns. In addition, scanning lines 55-1 to 55-m are wired for each row and signal lines 56-1 to 56-n are wired for each column in the matrix-like arrangement of the pixels 60, respectively. The pixel 60 includes a TFT (Thin Film Transistor) 61 which is a pixel transistor, a liquid crystal cell 62 in which a pixel electrode is connected to the drain electrode of the TFT 61, and a storage capacitor in which one electrode is connected to the drain electrode of the TFT 61. 63.

  In this pixel structure, the TFT 61 of each pixel 60 has its gate electrode connected to the scanning line 55 (55-1 to 55-m) and its source electrode connected to the signal line 56 (56-1 to 56-n). Has been. The counter electrode of the liquid crystal cell 62 and the other electrode of the storage capacitor 63 are connected to a common line 57 to which a common voltage VCOM is applied.

  The vertical driver 52 includes a shift register or the like, and selects each pixel 60 of the pixel array unit 51 in units of rows. The horizontal driver 52 is configured by a shift register, a sampling switch, and the like. For each pixel 60 in the row selected by the vertical driver 52, video signals input from the outside of the panel are sequentially displayed in units of pixels (dot sequential). Alternatively, data is written simultaneously (line-sequentially) in units of lines.

  The power supply voltage generation circuit 54 is, for example, a circuit that generates a negative power supply voltage, and is built in to supply a negative power supply voltage to the peripheral drive circuit of the pixel array unit 51, for example, the vertical driver 52. As the power supply voltage generation circuit 54, the power supply voltage generation circuits 30 and 40 according to the application examples 1 and 2 described above are used.

  The power supply voltage generation circuit 54 is, for example, a clock pulse having a higher frequency than the vertical clock pulse VCK input to the vertical driver 52 as a reference for vertical scanning, for example, a horizontal clock pulse HCK input to the horizontal driver 53 as a reference for horizontal scanning. And a negative power supply voltage is generated by operating based on the horizontal clock pulse HCK and supplied to the negative power supply line of the output stage of the vertical driver 52.

  That is, the horizontal clock pulse HCK corresponds to the clock pulse CK that is input to the level shift unit 31 in the power supply voltage generation circuits 30 and 40 according to the application examples 1 and 2 described above. The input clock pulse of the power supply voltage generation circuit 54 is not limited to the horizontal clock pulse HCK.

  Peripheral drive circuits such as the vertical driver 52, the horizontal driver 53, and the power supply voltage generation circuit 54 are formed on a liquid crystal panel (insulating substrate) 55 together with the pixel array unit 51 using polysilicon TFTs.

  Incidentally, in recent years, there has been an increasing demand for higher performance and higher image quality such as lower voltage and higher contrast in liquid crystal display devices. In general, high contrast and low voltage are contradictory requirements. That is, in order to increase the contrast, it is necessary to increase the amplitude of the video signal input to the liquid crystal display device. As a result, the drive voltage of the liquid crystal display device becomes high and cannot be lowered. Conversely, to lower the voltage, the amplitude of the video signal is reduced, and as a result, the contrast tends to decrease.

  In order to satisfy both low voltage and high contrast at the same time, the level on the low voltage side of the video signal is lowered as much as possible (that is, close to the ground side), and the stop value of the video signal is also lowered. It is conceivable to adopt a method of lowering the high voltage side of the video signal while increasing the dynamic range of the signal.

  However, when the above method is adopted, in the pixel 60 shown in FIG. 14, if the threshold value Vth of the TFT 61 that holds the high voltage side of the video signal is depleted, the scanning line 55 (55-1 to 55-m). Is 0 [V], and when the signal line 56 (56-1 to 56-n) is at the low level, there is a concern that a so-called leaky luminescent spot may be formed in which the TFT 61 leaks and becomes a luminescent spot. However, if the low level of the scanning line 55 (55-1 to 55-m) can be set to a negative potential, a sufficient margin for this leaky luminescent spot can be secured.

  Therefore, as described above, in the drive circuit integrated liquid crystal display device 50, the power supply voltage generation circuit 54 is integrated on the liquid crystal panel 58 as one of the peripheral drive circuits, and the negative power supply generated by the power supply voltage generation circuit 54 is obtained. By supplying the voltage to the vertical driver 52 and setting the low level of the scanning line 55 (55-1 to 55-m) to a negative potential, the level on the low voltage side of the video signal is lowered as much as possible, and the video is also displayed. Lowering the signal stop value and raising the dynamic range of the video signal while lowering the high voltage side of the video signal can be adopted, so both low voltage and high contrast can be achieved without causing leaky bright spots. Can be realized simultaneously.

  Further, since the power supply voltage generation circuit 54 is formed on the liquid crystal panel 58, it is not necessary to provide a power supply voltage generation circuit outside the liquid crystal panel 58, and a terminal for taking in the negative power supply voltage from the outside of the panel becomes unnecessary. Therefore, the set design burden can be reduced.

  Further, by using the power supply voltage generation circuits 30 and 40 according to the above-described application examples 1 and 2 as the power supply voltage generation circuit 54, in the power supply voltage generation circuits 30 and 40, the level conversion circuit 10, By using 20, the leakage current can be prevented and the power consumption can be reduced, so that the power consumption of the liquid crystal display device 50 can be reduced.

  In particular, when the power supply voltage generation circuit 40 according to the application example 2 is used as the power supply voltage generation circuit 54, the power supply voltage generation circuit 54 generates the reset pulse rst internally in addition to performing the circuit operation with reliability. Since the reset pulse rst need not be taken in from the outside of the liquid crystal panel 58, there is an advantage that it is not necessary to provide a dedicated terminal for taking in the reset pulse rst.

  In the application example described above, the case where the negative power supply voltage generated by the power supply voltage generation circuit 54 is supplied to the vertical driver 52 has been described as an example. However, the present invention is not limited to the supply to the vertical driver 52. All peripheral drive circuits that require voltage are subject to supply. Further, the power supply voltage generation circuit 54 is not limited to a circuit that generates a negative power supply voltage, but may of course be a circuit that generates a positive power supply voltage.

  In the above application example, the case where the present invention is applied to a liquid crystal display device using a liquid crystal cell as an electro-optic element of the pixel has been described as an example. However, the present invention is not limited to application to a liquid crystal display device. For example, an EL display device using an EL (electro luminescence) element as an optical element can be applied to all display devices in which a drive circuit for a negative power supply voltage is formed on the same substrate as the pixel array portion.

  A display device typified by the liquid crystal display device according to the application example described above can be mounted and used as a screen display unit of a mobile device such as a mobile phone, a PDA (Personal Digital Assistants), and a notebook PC (Personal Computer).

1 is a circuit diagram showing a configuration of a level conversion circuit according to a first embodiment of the present invention. 6 is a timing chart for explaining a basic circuit operation of the level conversion circuit according to the first embodiment when a circuit operation control signal xstb is in an active state. 6 is a timing chart showing recommended timing of the circuit operation control signal xstb with respect to the clock pulse CK. 6 is a timing chart showing a timing relationship when the circuit operation control signal xstb rises to High while the clock pulse CK is Low. It is a circuit diagram which shows the structure of the level conversion circuit which concerns on 2nd Embodiment of this invention. It is a timing chart with which it uses for description of the circuit operation | movement of the level conversion circuit which concerns on 2nd Embodiment. It is a block diagram which shows the structure of the power supply voltage generation circuit which concerns on the application example 1 of this invention. It is a block diagram which shows an example of a structure of a buffer part. It is a circuit diagram which shows an example of a structure of an inverter circuit. It is a circuit diagram which shows an example of a structure of a negative power supply generation part. It is a block diagram which shows the structure of the power supply voltage generation circuit which concerns on the application example 2 of this invention. It is a circuit diagram which shows an example of a structure of a NAND circuit. It is a timing chart which shows the timing relationship which produces | generates the reset pulse rst based on the output x1, x2 of a buffer part. It is a block diagram which shows an example of a structure of the active matrix type liquid crystal display device which concerns on the application example of this invention. It is a circuit diagram which shows an example of a structure of the current mirror type | mold level conversion circuit which concerns on a prior art example.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Level conversion circuit which concerns on 1st Embodiment, 11 ... Complementary circuit, 12 ... Inverter, 13 ... 1st switch circuit, 14 ... 2nd switch circuit, 15 ... 3rd switch circuit, 16 ... One direction , 20... Level conversion circuit according to the second embodiment, 21... Reset circuit, 30... Power generation circuit according to application example 1, 31... Level shift unit, 32. DESCRIPTION OF SYMBOLS ... NAND circuit, 40 ... Power supply generation circuit concerning application example, 50 ... Liquid crystal display device, 51 ... Pixel array part, 52 ... Vertical driver, 53 ... Horizontal driver, 54 ... Power supply voltage generation circuit, 58 ... Liquid crystal panel, 60 ... Pixel, 61 ... TFT (Thin Film Transistor), 62 ... Liquid Crystal Cell, 63 ... Retention Capacity, C ... Capacitance Element

Claims (17)

First and second transistors of opposite conductivity type connected in series between a first power supply potential and a second power supply potential;
A clock terminal to which a clock signal is input;
A first switch connected between the clock terminal and the gate of the first transistor and turned on when a circuit operation control signal is in an active state; the second power supply potential; and the second transistor A second switch means connected between the first and second gates and turned off when the circuit operation control signal is in an active state;
A level conversion circuit comprising: a capacitor connected between the clock terminal and the gate of the second transistor. The level conversion circuit according to claim 1, further comprising a unidirectional circuit connected between the second power supply potential and a gate of the second transistor. The level conversion circuit according to claim 1, wherein the circuit operation control signal transitions from an inactive state to an active state when the clock signal is at a high level. The level conversion circuit according to claim 1, further comprising reset means for periodically determining the gate potential of the second transistor at the second power supply potential. 5. The level according to claim 4, wherein the reset means is connected between the second power supply potential and the gate of the second transistor, and is turned on when the clock signal is at a high level. Conversion circuit. Level conversion means for converting the level of the clock pulse having the first amplitude into the clock pulse having the second amplitude;
Buffer means for converting the clock pulses of the second amplitude level-converted by the level conversion means into clock pulses of opposite phases to each other,
A power supply voltage generating circuit that operates based on the opposite-phase clock pulses output from the buffer means and generates a predetermined power supply voltage;
The level converting means includes
First and second transistors of opposite conductivity type connected in series between a first power supply potential and a second power supply potential;
A clock terminal to which a clock signal is input;
A first switch connected between the clock terminal and the gate of the first transistor and turned on when a circuit operation control signal is in an active state; the second power supply potential; and the second transistor A second switch means connected between the first and second gates and turned off when the circuit operation control signal is in an active state;
A power supply voltage generation circuit comprising: a capacitor connected between the clock terminal and the gate of the second transistor. The power supply voltage generation circuit according to claim 6, wherein the level conversion means further includes a unidirectional circuit connected between the second power supply potential and the gate of the second transistor. The power supply voltage generation circuit according to claim 6, wherein the circuit operation control signal transitions from an inactive state to an active state when the clock signal is at a high level. The power supply voltage generation circuit according to claim 6, wherein the level conversion means further comprises reset means for periodically determining the gate potential of the second transistor at the second power supply potential. The power supply according to claim 9, wherein the reset means is connected between the second power supply potential and the gate of the second transistor, and is turned on when the clock signal is at a high level. Voltage generation circuit. The buffer means comprises an odd number of inverter circuits connected in cascade.
The power supply voltage generation circuit according to claim 10, further comprising means for generating a reset signal for driving and controlling the reset means using an output of an arbitrary inverter circuit in the buffer means. Level conversion means for converting the level of the clock pulse having the first amplitude into the clock pulse having the second amplitude;
Buffer means for converting the clock pulses of the second amplitude level-converted by the level conversion means into clock pulses of opposite phases to each other,
A power supply voltage generating circuit that operates based on the opposite-phase clock pulses output from the buffer means and generates a predetermined power supply voltage;
A display device in which pixels including electro-optic elements are formed on the same substrate as a pixel array unit in which pixels are two-dimensionally arranged in a matrix,
The level converting means includes
First and second transistors of opposite conductivity type connected in series between a first power supply potential and a second power supply potential;
A clock terminal to which a clock signal is input;
A first switch connected between the clock terminal and the gate of the first transistor and turned on when a circuit operation control signal is in an active state; the second power supply potential; and the second transistor A second switch means connected between the first and second gates and turned off when the circuit operation control signal is in an active state;
A display device comprising: a capacitor connected between the clock terminal and a gate of the second transistor. The display device according to claim 12, wherein the level conversion unit further includes a unidirectional circuit connected between the second power supply potential and a gate of the second transistor. The display device according to claim 12, wherein the circuit operation control signal transitions from an inactive state to an active state when the clock signal is at a high level. The display device according to claim 12, wherein the level conversion unit further includes a reset unit that periodically determines the gate potential of the second transistor to be the second power supply potential. The display according to claim 12, wherein the reset unit is connected between the second power supply potential and the gate of the second transistor, and is turned on when the clock signal is at a high level. apparatus. The buffer means comprises an odd number of inverter circuits connected in cascade.
The display device according to claim 16, further comprising means for generating a reset signal for driving and controlling the reset means using an output of an arbitrary inverter circuit in the buffer means.

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