JP6495670B2 - LED drive circuit - Google Patents

Description

  The present invention relates to an LED drive circuit that drives an LED (Light Emitting Diode).

  LEDs, particularly white LEDs, are used for various lighting devices such as backlights for liquid crystal displays and various lighting fixtures. In such illumination applications, it may be required to control the brightness of each LED so that the plurality of LEDs emit light with the same brightness.

  The brightness of the LED varies depending on the current flowing through the element. For this reason, when controlling the brightness | luminance of several LED, it is calculated | required to control precisely the electric current which flows into each LED according to control signals, such as the electric current at the time of LED drive, or a voltage.

  Conventionally, a circuit as shown in FIG. 8 has been used as an LED drive circuit for lighting an LED at a constant current. FIG. 8 is a circuit diagram showing a configuration of a first example of a conventional LED driving circuit. The LED drive circuit shown in FIG. 8 includes an LED 81 that is a load of the LED drive circuit, a reference current source (Ir1) 65 that outputs a reference current for controlling the current flowing through the LED 81, and a reference resistance element (R1) through which the reference current flows. 51, a detection resistance element (R2) 52 for detecting a current flowing through the LED 81, an amplifier (AMP1) 61 using a differential amplifier for amplifying a potential difference between voltages generated in the reference resistance element 51 and the detection resistance element 52, an amplifier 61 A current control element (M1) 63 such as a MOSFET for controlling the current flowing in the LED 81 based on the output signal is provided.

  A reference voltage Vr1 is generated between both terminals of the reference resistance element 51 by the reference current Ir1 output from the reference current source 65 and the reference resistance element 51. On the other hand, a detection voltage Vs1 is generated between both terminals of the detection resistance element 52 by the load current IL flowing through the LED 81 and the detection resistance element 52 by the power supplied from the voltage source (V1) 76. The difference between the reference voltage Vr1 and the detection voltage Vs1 is amplified by the amplifier 61, and the gate voltage of the current control element 63 is controlled, so that the reference voltage Vr1 and the reference voltage Vr1 are reduced by a negative feedback action via the amplifier 61 and the current control element 63. The detection voltage Vs1 is controlled to be equal. As a result, the relationship between the reference current Ir1 and the load current IL flowing through the LED is controlled as in the following formula (1).

ＩＬ：負荷電流、Ｒ１：参照抵抗素子５１の抵抗値、Ｒ２：検出抵抗素子５２の抵抗値、Ｉｒ１：参照電流（参照電流源６５からの出力電流）

IL: load current, R1: resistance value of the reference resistance element 51, R2: resistance value of the detection resistance element 52, Ir1: reference current (output current from the reference current source 65)

  In the configuration of FIG. 8, the ratio of the resistance values of the reference resistance element 51 and the detection resistance element 52 is set to a value such as R1: R2 = 1000: 1, for example, and the reference current Ir1 is changed to flow through the LED 81. The load current IL is controlled in proportion to the resistance value ratio R1 / R2. Here, the reference resistance element 51 and the detection resistance element 52 are configured by resistance elements having the same temperature coefficient, so that the ratio of the resistance values changes even if the absolute value of the resistance value changes due to a change in the ambient temperature. The characteristics are difficult to perform. Using this characteristic, an LED drive circuit that supplies a stable output current to the load with respect to the ambient temperature can be configured.

  In the LED drive circuit of FIG. 8, error elements of the load current IL that drives the LED 81 include a shift in the relative values of the resistance values of the reference resistance element 51 and the detection resistance element 52 and the input offset voltage of the amplifier 61. . The load current IL including the input offset voltage of the amplifier 61 is expressed by the following formula (2).

Ｖ_IO：増幅器６１の入力オフセット電圧

V _IO : Input offset voltage of the amplifier 61

The input offset voltage V _IO of the amplifier 61 is an input potential difference from the non-inverting input terminal with respect to the inverting input terminal of the amplifier 61. This input offset voltage V _IO is represented by a voltage source 77 virtually inserted into the non-inverting input terminal of the amplifier 61 in FIG.

Adjustment of the luminance (brightness) of the LED is performed by controlling the value of the reference current Ir1. When the value of the reference current Ir1 is decreased in order to decrease the luminance of the LED, the value of the first term part of the formula (2) is decreased, and the ratio of the term relating to the _{VIO of} the second term is increased. The ratio of the second term in Expression (2) corresponds to the ratio of the error element with the theoretical value of the load current IL according to Expression (1). For example, when the reference current Ir1 = 100 μA, the resistance value R1 of the reference resistance element 51 = 2000Ω, the resistance value R2 of the detection resistance element 52 = 2Ω, and the input offset voltage V _IO of the amplifier 61 = 2 mV, the input offset voltage of the amplifier 61 error due to V _IO is about 1%. In contrast, if the turning on darken LED81 as a reference current Ir1 = 10 .mu.A, the error due to the input offset voltage V _IO is also about 10%.

When a plurality of LEDs are driven with the same brightness by using a plurality of LED drive circuits of FIG. 8, when the error factor due to the input offset voltage _VIO is large, the LEDs are connected to each LED drive circuit when the brightness is lowered. There is a variation in the brightness of the LEDs, and in some cases, there is a problem that only specific LEDs are not lit. Therefore, the minimum value of the value of the reference current Ir1 is determined by considering the influence of the input offset voltage V _IO described above, in many cases, it has been in the order of 1 / 10-1 / 20 of the maximum current setting value .

  When the LED is turned on darkly by making the reference current Ir1 smaller than the minimum set value of the reference current Ir1, the load current flowing through the LED is turned on / off at a frequency of 100 Hz or more by PWM control or the like. A method of changing the time ratio between the lighting time and the lighting time is used. However, the method of turning on / off the LED in a short cycle causes problems such as generation of switching noise accompanying ON / OFF of the LED drive circuit and instability of the voltage on the anode side of the LED. For this reason, it is often required to drive the load current of the LED with a direct current and precisely control the current value of the load current.

  As a countermeasure for suppressing the influence of the input offset voltage of the amplifier in the LED drive circuit, for example, there is a conventional example described in Patent Document 1. FIG. 9 is a circuit diagram showing a configuration of a second example of a conventional LED drive circuit, and is a diagram showing an example of a configuration described in Patent Document 1. In FIG. Compared with the configuration of FIG. 8, the LED drive circuit shown in FIG. 9 includes a current generating transistor 69 using a MOSFET (M11) instead of the reference resistance element 51, and a plurality of MOSFETs (M12) instead of the detection resistance element 52. Are provided by replacing the current control transistors 70 connected in parallel with each other. In the current control transistor 70, the output of the current control circuit 73 is input to each gate of the plurality of MOSFETs, and the current control circuit 73 controls the on / off of the plurality of MOSFETs. In the configuration of FIG. 9, the load voltage flowing in the LED 81 is controlled by individually controlling the gate voltages of the MOSFETs connected in parallel in the current control transistor 70 by the current control circuit 73 and switching the on-resistance of the current control transistor 70 as a whole. The current is controlled.

JP 2010-135379 A

In the first example of the LED drive circuit according to the prior art as shown in FIG. 8, if the reduced load current flowing to the LED for lighting at low brightness, the input offset voltage V _IO amplifier 61, a reference current Ir1 The error rate in the proportional relationship with the load current IL increases. Therefore, there is a problem that the ratio between the reference current and the load current changes depending on the value of the load current flowing through the LED, and the accuracy of the load current control is lowered.

  Further, in the second example of the LED driving circuit according to the prior art as shown in FIG. 9, the resistance element for detecting the load current is replaced with a plurality of parallel-connected MOSFETs. In the case of the configuration of the second example, in order to finely control the gradation of the load current value flowing through the LED, a number of MOSFETs and a circuit for controlling these gate voltages are required. In addition, variation in characteristics among the plurality of MOSFETs affects the load current of the LED. In order to suppress variations in characteristics among a plurality of MOSFETs, it is necessary to reduce the influence of variations in the shape of the MOSFETs by increasing the gate length of each MOSFET. For this reason, the circuit scale becomes large and the problem that the layout area of MOSFET in a circuit becomes very large arises. Therefore, when controlling the load current of the LED, it is difficult to maintain the ratio between the reference current and the load current in a wide range.

  An object of the present invention is to provide an LED drive circuit capable of accurately maintaining a ratio between a reference current and a load current when controlling a load current of an LED.

The present invention includes a first detection resistance element and a second detection resistance element for detecting a load current flowing in an LED, a first current control element and a second current control element for controlling the load current, The first current control element and the second current control element are connected in parallel between the LED and the ground, the first current control element and the first detection resistance element, The second current control element and the second detection resistance element are respectively connected in series, and the first detection resistance element and the second detection resistance element are connected in series between the LED and the ground. A reference current source that outputs a reference current for controlling the load current, and a first reference resistance element and a second reference resistance element that generate a voltage proportional to the reference current. The first reference resistance element Wherein it is connected in series between the second reference resistance element and said reference current source and ground, and a voltage generated in the first reference resistance element, said generated in the first detection resistor element A first operation control circuit for controlling an operation of the first current control element according to a difference from a voltage proportional to a load current; a voltage generated in the second reference resistance element; and the second detection A second operation control circuit for controlling the operation of the second current control element in accordance with a difference from the voltage proportional to the load current generated in the resistance element; and the first operation in accordance with the magnitude of the reference current. has an operation control circuit and the driving circuit control unit for controlling the second operation control circuit, and the driving circuit control unit, when the magnitude of the reference current is less than the first predetermined value, the Turn on the second motion control circuit It operates the second current control element, and turns off the first operation control circuit stops the operation of said first current control element, to provide an LED drive circuit.
The present invention also provides a first detection resistance element and a second detection resistance element for detecting a load current flowing in the LED, and a first current control element and a second current control element for controlling the load current. The first current control element and the second current control element are connected in parallel between the LED and the ground, and the first current control element and the first detection resistor An element, the second current control element, and the second detection resistance element are connected in series, and the first detection resistance element and the second detection resistance element are connected in series between the LED and the ground. And a first reference current source that outputs a first reference current as a reference current for controlling the load current, and a second reference current that is proportional to the first reference current. A second reference current source; A first reference resistance element that generates a voltage proportional to the reference current of the second reference resistance element, and a second reference resistance element that generates a voltage proportional to the second reference current. Is connected between the second reference current source and ground, and a voltage generated in the first reference resistance element and a voltage proportional to the load current generated in the first detection resistance element The first operation control circuit that controls the operation of the first current control element according to the difference between the voltage, the voltage generated in the second reference resistance element, and the load generated in the second detection resistance element A second operation control circuit for controlling the operation of the second current control element according to a difference from a voltage proportional to a current; the first operation control circuit according to the magnitude of the reference current; 2 control operation control circuit And the drive circuit control unit turns on the second operation control circuit and turns on the second current when the magnitude of the reference current is less than a first predetermined value. Provided is an LED drive circuit that operates a control element and turns off the first operation control circuit to stop the operation of the first current control element.

  ADVANTAGE OF THE INVENTION According to this invention, the LED drive circuit which can keep the ratio of a reference current and load current with a sufficient precision can be provided.

It is a circuit diagram which shows the structure of the LED drive circuit of 1st Embodiment. It is a circuit diagram which shows the specific structural example of the LED drive circuit of 1st Embodiment. It is a characteristic view which shows the relationship between the load current in the LED drive circuit of 1st Embodiment, and the error rate by the input offset voltage of an amplifier. It is a circuit diagram which shows the structure of the LED drive circuit of 2nd Embodiment. It is a circuit diagram which shows the specific structural example of the LED drive circuit of 2nd Embodiment. It is a circuit diagram which shows the structure of the LED drive circuit of 3rd Embodiment. It is a circuit diagram which shows the specific structural example of the LED drive circuit of 3rd Embodiment. It is a circuit diagram which shows the structure of the 1st example of the conventional LED drive circuit. It is a circuit diagram which shows the structure of the 2nd example of the conventional LED drive circuit. It is a circuit diagram which shows the structure of the LED drive circuit of a comparative example.

  Hereinafter, an embodiment (hereinafter referred to as “the present embodiment”) that specifically discloses an LED drive circuit according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
FIG. 1 is a circuit diagram showing the configuration of the LED drive circuit of the first embodiment. The LED drive circuit of the first embodiment includes an LED 31 that is a load of the LED drive circuit, a first detection resistance element (R2) 2 and a second detection resistance element (R4) 4 for detecting a load current. The first current control element (M1) 10 and the second current control element (M2) 11 for controlling the load current are provided. In addition, as an example of the reference current generation unit, a first reference current source (Ir1) 24 that outputs a reference current Ir1, a first reference resistance element (R1) 1 that generates a voltage proportional to the reference current, a second The reference resistance element (R3) 3 is provided. In addition, as an example of a first operation control circuit that controls the operation of the first current control element 10, a first amplifier (AMP 1) 22 using a differential amplifier is provided, and the operation of the second current control element 11 is controlled. As an example of the second operation control circuit, a second amplifier (AMP2) 23 using a differential amplifier is provided. Furthermore, as an example of the drive circuit control unit, a current detection circuit 32 that turns on / off the operations of the first amplifier 22 and the second amplifier 23 based on the magnitude of the reference current (detection current value) is provided.

At one end of the LED 31, a first current control element 10 and a second current control element 11 such as an Nch MOSFET for controlling a load current IL flowing through the LED 31 are parallel to the LED 31 between the LED 31 and the ground. Connected. The first detection resistance element 2 for detecting the first load current I _o1 of the load current IL is connected in series to the first current control element 10, and one end of the first detection resistance element 2 is connected. Is grounded. A second detection resistance element 4 for detecting the second load current I _o2 of the load current IL is connected in series to the second current control element 11, and one end of the second detection resistance element 4 is connected. Is connected to the connection point between the source of the first current control element 10 and the first detection resistance element 2. Accordingly, the second detection resistance element 4 and the first detection resistance element 2 are connected in series to the LED 31 between the LED 31 and the ground (path through which the load current IL flows).

  A current detection circuit 32 that detects the value of the reference current Ir1 is inserted in a path through which the reference current Ir1 output from the first reference current source 24 flows. The first reference current source 24 is a current source configured to change the output current value. The second reference resistance element 3 and the first reference resistance element 1 are connected in series to the output terminal of the first reference current source 24, and one end of the first reference resistance element 1 is grounded. The connection point between the first reference resistance element 1 and the second reference resistance element 3 is connected to the non-inverting input terminal of the first amplifier 22, and the inverting input terminal of the first amplifier 22 is connected to the first current. A connection point between the control element 10 and the first detection resistance element 2 is connected. A non-inverting input terminal of the second amplifier 23 is connected to a connection point between the second reference resistance element 3 and the first reference current source 24, and the inverting input terminal of the second amplifier 23 is a second current. A connection point between the control element 11 and the second detection resistance element 4 is connected. The output terminal of the first amplifier 22 is connected to the control terminal (gate) of the first current control element 10, and the output terminal of the second amplifier 23 is connected to the control terminal (gate) of the second current control element 11. Is done. A detection output terminal of the current detection circuit 32 is connected to control input terminals of the first amplifier 22 and the second amplifier 23.

  Note that the first current control element 10 and the second current control element 11 are not limited to MOSFETs, and other elements or circuits capable of adjusting the load current IL, such as bipolar transistors, may be used. In addition, the first operation control circuit and the second operation control circuit are not limited to amplifiers, and the first current control element 10 and the second operation control circuit such as a comparator may be used depending on the ratio between the reference current Ir1 and the load current IL. Other elements and circuits may be used as long as the operation of the current control element 11 can be controlled.

  In the present embodiment, a detection resistance element for generating a voltage proportional to the load current IL for detecting the load current IL flowing through the load of the LED 31 and a voltage proportional to the reference current Ir1 by generating the reference current Ir1 are generated. A reference resistance element. Further, an amplifier that compares the voltages generated in the detection resistance element and the reference resistance element and amplifies the difference between the two voltages, and a load current that is inserted between the LED 31 and the detection resistance element and flows to the LED 31 by the output voltage of the amplifier. A current control element for controlling IL, and controls the load current IL so as to obtain a current value corresponding to the reference current Ir1.

  Here, the first detection resistance element 2 and the second detection resistance element 4 are provided as detection resistance elements, the first current control element 10 and the second current control element 11 are provided as current control elements, The second detection resistance element 4 is connected to a connection point between the first detection resistance element 2 and the first current control element 10, and the first detection resistance element 2 and the second detection resistance element 4 are connected in series. Is done. The second current control element 11 is connected between the other end of the second detection resistance element 4 and the other end of the first current control element 10, and the first current control element 10 and the second current are connected. The control element 11 is connected in parallel. And it has the 1st reference current source 24 which generates reference current Ir1, has the 1st reference resistive element 1 and the 2nd reference resistive element 3 as a reference resistive element, A second reference resistance element 3 is provided between the first reference resistance element 1 and the first reference resistance element 1. Further, the amplifier has a first amplifier 22 and a second amplifier 23. The first amplifier 22 compares the potential difference generated in the first detection resistance element 2 and the first reference resistance element 1 and compares the first difference. The second amplifier 23 controls the second current control element 11 by comparing the potential difference generated between the second detection resistance element 4 and the second reference resistance element 3.

  Furthermore, it has a current detection circuit 32 for detecting the value of the reference current Ir1, and the current detection circuit 32 outputs a control signal corresponding to the detected current value to the first amplifier 22 and the second amplifier 23, and The operation of the amplifier 22 and the second amplifier 23 is controlled. Thereby, according to the value of the reference current Ir1 detected by the current detection circuit 32, the respective current control terminals of the first current control element 10 and the second current control element 11 are brought into a conductive state or a cut-off state. At this time, when the reference current Ir1 is less than a predetermined value, the first current control element 10 is turned off and the second current control element 11 is turned on. When the reference current Ir1 is equal to or greater than the predetermined value, the first current control element 10 is turned on. The second current control element 11 is configured to be turned off.

In the conventional LED driving circuit of the first example shown in FIG. 8, the error of the load current IL increases when the value of the reference current Ir1 decreases, which is related to the input offset voltage V _IO in the equation (2). This is because the second term is constant regardless of the value of the reference current Ir1. In order to reduce the influence of the terms related to _VIO , it is necessary to increase the resistance value R2 of the first detection resistance element 2. In order to maintain the relationship between the reference current Ir1 and the load current IL, the resistance value R1 of the first reference resistance element 1 must be changed in proportion to the change in the resistance value R2 of the first detection resistance element 2. Don't be.

  In consideration of the above reason, the second reference resistance element 3 and the second detection resistance element 4 are additionally provided in the present embodiment. The value of each resistance element is set as in the following formula (3).

Ｒ１：第１の参照抵抗素子１の抵抗値、Ｒ２：第１の検出抵抗素子２の抵抗値、Ｒ３：第２の参照抵抗素子３の抵抗値、Ｒ４：第２の検出抵抗素子４の抵抗値

R1: resistance value of the first reference resistance element 1, R2: resistance value of the first detection resistance element 2, R3: resistance value of the second reference resistance element 3, R4: resistance of the second detection resistance element 4 value

  Here, R3 and R4 are set to about 10 times the resistance values of R1 and R2, for example. That is, R1: R3 = R2: R4≈1: 10. R1: R2 = R3: R4≈1000: 1. Note that the ratios of these resistance values are merely examples, and may be set as appropriate according to the configuration of the LED drive circuit, usage conditions, etc. while maintaining the ratio at a constant value.

In a region where the reference current Ir1 is small, the load current IL is detected by the second detection resistance element 4 having a resistance value R4 that is larger than the resistance value R2 of the first detection resistance element 2, and second current control is performed. The load current IL is controlled only by the element 11. As a result, it is possible to reduce the influence of the term relating to the input offset voltage _VIO of the amplifier while maintaining the ratio of the reference current Ir1 and the load current IL.

  In order to realize the above operation, in the LED driving circuit of the first embodiment shown in FIG. 1, the value of the reference current Ir1 is detected, and the first amplifier 22 and the first amplifier 22 according to the magnitude of the reference current Ir1 are detected. And a current detection circuit 32 for controlling operation / stop by outputting a control signal to the control input terminal of the second amplifier 23. The first amplifier 22 and the second amplifier 23 are differential amplifiers having a control input terminal for switching operation / stop. For example, if the input voltage of the control input terminal is less than a predetermined value (0 V, low level). In this case, the operation is stopped and the output voltage is set to 0 V, and the differential amplifier is operated if the output voltage exceeds a predetermined value.

Using the above function, in the input offset voltage V _IO region high impact of the first amplifier 22 current value is small reference current Ir1, stops the control of the load current IL by the first amplifier 22, the resistance value The load current IL is detected by the second detection resistance element 4 having a large current and the load current IL is controlled by the second amplifier 23. That is, in order to reduce the reference current Ir1 so that the LED 31 emits light with low luminance, the first amplifier 22 is turned off to stop the operation of the first current control element 10, and the second amplifier 23, The load current IL is controlled by the current control element 11. When the current value of the reference current Ir1 becomes larger than the first predetermined value, the operation of the first amplifier 22 is started, and further, the current value of the reference current Ir1 is larger than the second predetermined value which is equal to or larger than the first predetermined value. When it becomes, it switches to control of load current IL by only the 1st amplifier 22 and the 1st current control element 10.

  FIG. 10 is a circuit diagram showing a configuration of an LED drive circuit of a comparative example. The comparative example shown in FIG. 10 has a configuration in which the LED drive circuit shown in FIG. 8 is connected in parallel in two circuits. That is, the first reference resistance element 1, the first detection resistance element 2, the first amplifier 22, the first control circuit by the first current control element 10, the second reference resistance element 3, the second reference resistance element 3 The detection resistance element 4, the second amplifier 23, and the second control circuit by the second current control element 11 are simply provided in parallel.

  If only the circuit for controlling the load current IL is switched, the configuration of the comparative example in FIG. 10 is also possible. However, in the configuration of FIG. 10, when two circuits operate simultaneously, the load current IL is the sum of the output currents of these two circuits, so that the current flowing through the LED 31 increases. As a result, when the control of the load current is switched from the control by the first amplifier 22 to the control by the second amplifier 23, the first amplifier 22 is temporarily stopped temporarily, and then the second amplifier 23 is operated. There is a problem that the load current temporarily stops and increases when the operation of the amplifier is switched. In addition, a complicated switching circuit is required for switching the amplifier.

  In order to solve the above problem, in the LED drive circuit of the first embodiment shown in FIG. 1, the first reference resistance element 1, the second reference resistance element 3, the first detection resistance element 2, and the second detection resistance The resistive elements 4 are connected in series. This configuration has an advantage that the load current IL can be controlled even when the first amplifier 22 and the second amplifier 23 are operating simultaneously.

In a state in which the first amplifier 22 and the second amplifier 23 are operating, the first load current I _o1 flowing through the first current control element 10 and the first detection resistance element 2, and the second current control The relationship between the second load current _Io2 flowing through the element 11 and the second detection resistance element 4 and the reference current Ir1 is expressed by the following equations (4) and (5).

From the above formulas (4) and (5), the first load current I _o1 and the second load current I _o2 are obtained by the following formulas (6) and (7), respectively.

In Equation (6), by setting the resistance value of each resistance element so that R1 / R2 = R3 / R4, I _o1 = 0 mA in the ideal state. As a result, the load current IL is controlled only by the negative feedback action of the second amplifier 23 and is not affected by the operation of the first amplifier 22. For this reason, it is possible to operate the first amplifier 22 and the second amplifier 23 simultaneously.

  As described above, in the first embodiment, the first reference resistance element 1 and the second reference resistance element 3, and the first detection resistance element 2 and the second detection resistance element 4 are connected in series. As a result, even in a region where the current control of the load current IL is switched, the effect of preventing the ratio of the reference current Ir1 and the load current IL from changing is obtained. Further, in the comparative example shown in FIG. 10, when the current control element is switched, the load current flowing through the LED 31 is temporarily increased or decreased, and a switching mechanism for suppressing a change in the load current is necessary. In contrast, in the present embodiment, since the first amplifier 22 and the second amplifier 23 can be operated together, a complicated switching mechanism is not required, and the current control element can be switched by a simple circuit. is there.

  FIG. 2 is a circuit diagram illustrating a specific configuration example of the LED drive circuit according to the first embodiment. Corresponding to the configuration of FIG. 1, the LED 31, the first reference resistance element (R1) 1, the second reference resistance element (R3) 3, the first detection resistance element (R2) 2, and the second detection resistance element (R4) 4, a first current control element (M1) 10, a second current control element (M2) 11, a first amplifier (AMP1) 22, and a second amplifier (AMP2) 23 are provided.

  A driving voltage source (V1) 33 is connected to the LED 31, and the load current IL flows by the power supplied from the voltage source 33, and the LED 31 emits light. At this time, the load current IL is controlled by the first current control element 10 and the second current control element 11.

  As a first operation control circuit for operating / stopping the first amplifier 22, a switch element (M 7) 15 such as an Nch MOSFET is connected to the output terminal of the first amplifier 22. A resistance element (R5) 5 is connected between the connection point between one end of the switch element 15 and the control terminal (gate) of the first current control element 10 and the ground, and the control terminal (gate) of the switch element 15 A resistance element (R7) 7 is connected between the ground and the ground.

  As a second operation control circuit for operating / stopping the second amplifier 23, a switch element (M8) 16 such as an Nch MOSFET is connected to the output terminal of the second amplifier 23. A resistance element (R6) 6 is connected between the connection point between one end of the switch element 16 and the control terminal (gate) of the second current control element 11 and the ground, and the control terminal (gate) of the switch element 16 And a voltage element is connected to a resistance element (R8) 8.

  Further, the current detection circuit 32 includes a current mirror circuit constituted by transistors (M3) 12, (M4) 13, and (M5) 14 made of PchMOSFET or the like. The sources of the transistors 12, 13 and 14 are connected to the voltage source, the drain of the transistor 12 is connected to the first reference current source 24, the drain of the transistor 13 is connected to the second reference resistance element 3, and The drain is connected to the resistance element 7. In the current mirror circuit including the transistors 12, 13, and 14, the drain current of the transistor 13 is ideally the same value as the reference current Ir1 output from the first reference current source 24.

  A switch element (M9) 17 such as an Nch MOSFET is connected between a connection point between the control terminal (gate) of the switch element 16 and the resistance element 8 and the ground. A control terminal (gate) of the switch element 17 is connected to a connection point between the transistor 13 and the second reference resistance element 3 (non-inverting input terminal of the second amplifier 23).

  The operation of the LED drive circuit shown in FIG. 2 will be described step by step as the reference current Ir1 changes from a small value to a large value.

  First, when the value of the reference current Ir1 is smaller than the first predetermined value and the drain currents of the transistors 13 and 14 are small in proportion thereto, the potential difference generated in the resistance element 7 through which the drain current of the transistor 14 flows is also small. In this case, the switch element 15 by the Nch MOSFET is in an off state because the potential difference between the gate and the source does not reach the threshold voltage. Therefore, the gate voltage of the first current control element 10 that controls the load current IL is pulled down to the ground level by the resistance element 5, and the first current control element 10 that is also an Nch MOSFET is also turned off. As a result, the load current IL flowing through the LED 31 is controlled by the second amplifier 23 and the second current control element 11.

  As described above, since the resistance value R3 of the second reference resistance element 3 is several times larger than the resistance value R1 of the first reference resistance element 1, the second reference resistance element 3 has a second value even if the current value of the reference current Ir1 is small. A sufficiently large potential difference is generated in the reference resistance element 3 as compared with the input offset voltage of the second amplifier 23. Due to these effects, the proportional relationship (ratio) between the reference current Ir1 and the load current IL is kept substantially constant.

  Next, when the value of the reference current Ir1 increases, the potential difference in the resistance element 7 increases to reach the threshold voltage of the switch element 15 (when the reference current Ir1 becomes equal to or higher than the first predetermined value), the switch element 15 turns on. Here, consider a case where both the switch element 15 and the switch element 16 are in the ON state. In this state, either the first current control element 10 or the second current control element 11 can control the load current IL. However, as shown in the equations (6) and (7), R1 / When the proportional relationship of R3 = R3 / R4 is maintained, the drain current of the first current control element 10 hardly flows, and the load current is the same as in the case where the value of the reference current Ir1 is less than the first predetermined value. IL is mainly controlled by the second amplifier 23 and the second current control element 11.

Further, when the value of the reference current Ir1 increases and the gate voltage of the switch element 17 by the Nch MOSFET reaches the threshold voltage of the switch element 17 (when the reference current Ir1 becomes equal to or higher than the second predetermined value), the switch element 17 Turn on. For this reason, the gate voltage of the switch element 16 is lowered, and the switch element 16 gradually shifts from the on state to the off state. Further, the gate voltage of the second current control element 11 is lowered to 0 V, and the second load current I _o2 that is the drain current of the second current control element 11 is decreased. Since the decrease in the second load current I _o2 leads to a decrease in the voltage generated in the first detection resistance element 2 at the same time, the negative feedback operation via the first amplifier 22 and the first current control element 10 is performed. As a result, the first load current I _o1 starts to flow, and the value of the load current IL that is the sum of the first load current I _o1 and the second load current I _o2 is maintained at a value proportional to the reference current Ir1. When the value of the reference current Ir1 further increases, the second current control element 11 is turned off, and the load current IL is completely switched to the control by the first current control element 10.

  FIG. 3 is a characteristic diagram showing the relationship between the load current and the error rate due to the input offset voltage of the amplifier in the LED drive circuit of the first embodiment. In FIG. 3, the horizontal axis represents the load current IL, and the vertical axis represents the error rate between the ideal value of the load current expressed by Equation (1) and the value of the load current IL that actually flows through the LED. Yes.

Here, the error rate IL _ERR is defined by the following equation (8).

In FIG. 3, the characteristic indicated by the broken line is the relationship between the load current and the error rate in the first example of the conventional LED drive circuit of FIG. In the region where the load current IL is large, the error rate IL _ERR due to the input offset voltage of the amplifier is small, but increases in inverse proportion as the load current IL decreases. That is, the load current IL and the error rate IL _ERR are in an inversely proportional relationship.

On the other hand, the characteristic indicated by the solid line is the relationship between the load current and the error rate by the LED drive circuit of the first embodiment of FIG. In the region where the load current IL is large, the load current IL is controlled by the first current control element 10, and the load current IL and the error rate IL _ERR are in an inversely proportional relationship as in the conventional example. In the present embodiment, when the load current IL decreases from a large state to less than a predetermined value, the control of the load current IL is switched to the second current control element 11, and the resistance value R2 of the first detection resistance element 2 is set to the second value. The resistance value R4 of the detection resistance element 4 is switched. Therefore, the resistance value R2 of the detection resistance element in the mathematical formula (2) corresponding to the load current IL in the mathematical formula (8) is switched to the large resistance value R4. As a result, the ratio of error elements due to the input offset voltage of the amplifier decreases, and it can be seen that the error rate IL _ERR decreases as the operation of the current control element is switched. In the error rate IL _ERR characteristic of the solid line in FIG. 3, the region where the error rate IL _ERR decreases as the load current IL decreases decreases both in the first current control element 10 and the second current control element 11. In the region where the load current IL is small, only the second current control element 11 operates, and the error rate IL _ERR is kept small.

  As described above, in the present embodiment, the operations of the first current control element 10 and the second current control element 11 are switched according to the current value of the reference current Ir1, and in a region where the reference current Ir1 is smaller than a predetermined value. Only the second current control element 11 is operated to control the load current IL. By this operation, in the region where the load current IL is small, the second current control element 11 is controlled by the potential difference generated between the second detection resistance element 4 and the second reference resistance element 3 having a large resistance value, and the load current IL is controlled. As a result, the influence of the input offset voltage of the amplifier can be reduced while maintaining the ratio between the reference current Ir1 and the load current IL, and the ratio between the reference current and the load current can be increased over a wide range from a small current value to a large current value. It becomes possible to keep the accuracy. Therefore, the accuracy of the control value of the load current can be maintained even when the set value of the LED drive current is reduced, and the adjustment range of the brightness of the LED can be expanded.

(Second Embodiment)
FIG. 4 is a circuit diagram showing the configuration of the LED drive circuit of the second embodiment. Compared with the first embodiment shown in FIG. 1, the LED drive circuit of the second embodiment deletes the function of turning on / off the second current control element 11 and instead has a voltage higher than a predetermined value. Is connected to the second reference resistance element 3 in parallel with the second reference resistance element 3, and even if the value of the reference current Ir1 exceeds a predetermined value, the second reference resistance element 3 A function of limiting the generated potential difference to a constant value is provided. The current detection circuit 35 outputs a control signal corresponding to the detected current value of the reference current Ir1 only to the first amplifier 22. Here, only parts different from the circuit configuration of FIG. 1 will be described, and description of similar components will be omitted.

  In the second embodiment, as another example of the drive circuit control unit, the current detection circuit 35 that turns on / off the operation of the first amplifier 22 based on the detected current value of the reference current, and the magnitude of the reference current are And a limiting circuit that limits a voltage generated in the second reference resistance element 3 when it becomes equal to or higher than a third predetermined value that is equal to or higher than the first predetermined value. Here, as an example of the limiting circuit, the voltage generated in the second reference resistance element 3 is maintained at a predetermined value or less (a constant value) even when the reference current becomes equal to or higher than a third predetermined value. The example provided with the clamp circuit 34 which suppresses operation | movement is shown. In this configuration, when the reference current becomes equal to or higher than the third predetermined value, the operation of the second amplifier 23 and the second current control element 11 is not stopped, the clamp circuit 34 is turned on, and the current flows. The potential difference between the terminals of the second reference resistance element 3 is held so as not to exceed a predetermined value. The limiting circuit is not limited to the clamp circuit, and other elements and circuits such as a limiter circuit may be used.

  In the clamp circuit 34, a current flows when the value of the reference current Ir1 exceeds a third predetermined value, and the potential difference between both ends of the second reference resistance element 3 connected in parallel with the clamp circuit 34 is clamped to a constant value. The current flowing through the second current control element 11 does not increase any more and becomes a constant value. When the value of the reference current Ir1 further increases, the current flowing through the first current control element 10 increases, and the control of the load current IL is gradually switched to the control by the first current control element 10.

  In a region where the current value of the reference current Ir1 is small, as in the first embodiment, the first amplifier 22 is turned off to stop the operation of the first current control element 10, and the second amplifier 23, The load current IL is controlled by the current control element 11. When the current value of the reference current Ir1 becomes larger than the first predetermined value, the operation of the first amplifier 22 is started, and when the current value of the reference current Ir1 becomes larger than the third predetermined value (of the clamp circuit 34) When the operating voltage is exceeded), the operations of the second amplifier 23 and the second current control element 11 are limited as described above.

  The configuration of the second embodiment eliminates the need for a circuit for on / off control of the operation of the second amplifier 23, and thus realizes an LED drive circuit having the same effect as that of the first embodiment with a simpler configuration. it can.

  FIG. 5 is a circuit diagram illustrating a specific configuration example of the LED drive circuit according to the second embodiment. Here, only parts different from the circuit configuration of the first embodiment shown in FIG. 2 will be described, and description of similar components will be omitted.

  A diode (D1) 30 corresponding to the clamp circuit 34 of FIG. 4 is provided as a second operation control circuit for controlling the operation of the second amplifier 23, and both ends of the second reference resistance element (R3) 3 are provided. Connected in parallel. Compared with the configuration of FIG. 2, the resistance element (R6) 6 and the switch element (M8) 16 for reducing the gate voltage of the second current control element 11 are omitted, and the resistance element (R8) for controlling the switch element 16 is omitted. ) 8 and the switch element (M9) 17 are omitted.

  The operation of the LED drive circuit shown in FIG. 5 will be described. Similarly to the first embodiment, when the value of the reference current Ir1 is smaller than the first predetermined value and the drain currents of the transistors 13 and 14 are small in proportion thereto, the switch element 15 and the first current control element 10 Is off. In this case, the load current IL flowing through the LED 31 is controlled by the second amplifier 23 and the second current control element 11.

  Next, when the value of the reference current Ir1 increases and the potential difference in the resistance element 7 reaches the threshold voltage of the switch element 15 (when the reference current Ir1 becomes equal to or higher than the first predetermined value), the switch element 15 is turned on. Then, the first current control element 10 is turned on. However, in this state, the drain current of the first current control element 10 hardly flows, and the load current IL is mainly the same as that of the second amplifier 23 as in the case where the value of the reference current Ir1 is less than the first predetermined value. It is controlled by the second current control element 11.

  Therefore, in the LED drive circuit of FIG. 5, when the value of the reference current Ir1 is smaller than the third predetermined value and the potential difference between the terminals of the second reference resistance element 3 does not reach the threshold voltage of the diode 30, The load current IL flowing through the LED 31 is controlled by the second amplifier 23 and the second current control element 11.

When the value of the reference current Ir1 increases, the potential difference in the second reference resistance element 3 increases and reaches the threshold voltage of the diode 30 (when the reference current Ir1 becomes equal to or higher than the third predetermined value), the diode 30 Is turned on. In this state, even if the reference current Ir1 is further increased, the corresponding current flows to the diode 30 and the potential difference in the second reference resistance element 3 does not increase. In this case, the current value of the second load current I _o2 is represented by the following formula (9).

Ｖ_Ｆ：ダイオード３０の閾値電圧

V _F : threshold voltage of the diode 30

If a sufficiently low resistance value at the time of conduction of the diode 30, the current value of the second load current I _o2 is not increased beyond a predetermined value even by increasing the reference current Ir1. The increase in the reference current Ir1 when the diode 30 is in the ON state causes the first current control element 10 to pass current, and the load current IL is the first load current I which is the drain current of the first current control element 10. _o1 increases.

  In the LED drive circuit of FIG. 2, the switch element 17 is turned on as the reference current Ir1 increases, thereby turning off the second current control element 11. In the LED drive circuit of FIG. 5, the second current control is performed. The element 11 keeps flowing a constant current value. Therefore, the operation difference from the LED driving circuit of FIG. 2 is that both the first amplifier 22 and the second amplifier 23 continue to perform the negative feedback operation. The configuration of FIG. 5 does not require a circuit for turning on / off the second current control element 11, and thus has an advantage that the circuit configuration can be simplified.

  As described above, according to the second embodiment, the ratio between the reference current and the load current can be maintained with high accuracy even in a region where the current value is small as in the first embodiment. Further, the accuracy of the control value of the load current can be maintained over a wide range from a small current value region to a large current region with a simple circuit configuration.

(Third embodiment)
FIG. 6 is a circuit diagram showing the configuration of the LED drive circuit of the third embodiment. The LED drive circuit of the third embodiment is a second reference current source that outputs a current value proportional to the current value of the first reference current source 24, as compared with the first embodiment shown in FIG. (Ir2) 25, and the second reference resistance element 3 is not inserted between the first reference resistance element 1 and the first reference current source 24, but instead of the second reference current source 25 and the ground. Connected between. Here, only parts different from the circuit configuration of FIG. 1 will be described, and description of similar components will be omitted.

  In the third embodiment, as another example of the reference current generation unit, the first reference current source 24 and the second reference current source 25 are provided, and the first reference current source 24 and the ground are the first. The reference resistance element 1 is connected, and the second reference resistance element 3 is connected between the second reference current source 25 and the ground. That is, the reference current generation unit includes two reference current sources and a reference resistance element in parallel. In this case, a first reference current Ir1 is generated by the first reference current source 24, and a voltage proportional to the value of the first reference current Ir1 is generated in the first reference resistance element 1. Further, the second reference current Ir2 is generated by the second reference current source 25, and a voltage proportional to the value of the second reference current Ir2 is generated in the second reference resistance element 3. The second reference current Ir2 output from the second reference current source 25 increases or decreases in proportion to the first reference current Ir1, and flows through the second reference resistance element 3.

  In the LED driving circuit of FIG. 1, especially when the power supply voltage to which the first reference current source 24 is connected is low, when the reference current Ir1 is increased, the potential difference between the terminals of the second reference resistance element 3 becomes the power supply voltage. The first reference current source 24 composed of a MOSFET or the like may not pass an accurate current.

  On the other hand, in the configuration of the third embodiment, instead of connecting the first reference resistance element 1 and the second reference resistance element 3 in series, the first reference resistance element 1 and the second reference resistance element 1 are separated by a separate reference current source. The above problem can be avoided by supplying a reference current to each of the two reference resistance elements 3.

  FIG. 7 is a circuit diagram showing a specific configuration example of the LED drive circuit of the third embodiment. Here, only parts different from the circuit configuration of the first embodiment shown in FIG. 2 will be described, and description of similar components will be omitted.

  The LED drive circuit of FIG. 7 includes a transistor (M10) 18 such as a Pch MOSFET as a component corresponding to the second reference current source 25 that generates the second reference current Ir2 in the reference current generator. The transistor 18 has the same gate and source as the transistor (M4) 13, and the transistor 18 has the same gate width, gate length, and threshold voltage as the transistor 13. Further, the second reference resistance element 3 and the first reference resistance element 1 are not connected in series, the second reference resistance element 3 is connected to the drain of the transistor 18, and the first reference resistance element 1 Is connected to the drain of the transistor 13, and one ends of the first reference resistance element 1 and the second reference resistance element 3 are grounded.

  In the configuration of FIG. 7, the voltage generated in the second reference resistance element 3 due to the drain current of the transistor 18 is compared with the voltage generated in the second detection resistance element 4 by the second amplifier 23 to compare the second voltage. The current control element 11 is controlled.

  In the LED drive circuit of FIG. 2, a first reference resistance element 1 and a second reference resistance element 3 are connected in series. Here, it is assumed that the resistance value R3 of the second reference resistance element 3 is set to several tens of times the resistance value R1 of the first reference resistance element 1. In this case, there is no problem if the value of the reference current Ir1 is small. However, if the value of the reference current Ir1 is increased, the terminal voltage of the second reference resistance element 3 increases to the vicinity of the source voltage of the transistor 13, and the current mirror The accuracy of the current ratio with the transistor 12 constituting the circuit is lost. As a result, an error occurs in the reference current Ir1 flowing through the first reference resistance element 1 and the second reference resistance element 3, and the current ratio between the reference current Ir1 and the load current IL cannot be maintained.

The LED drive circuit of FIG. 7 is a countermeasure circuit for the above-described problem, and does not connect the first reference resistance element 1 and the second reference resistance element 3 in series, but allows a current to flow in proportion to the drain current of the transistor 13. The second reference resistance element 3 is connected to the drain of 18. For this reason, even if the terminal voltage of the second reference resistance element 3 reaches near the source voltage of the transistor 18, the value of the second load current I _o2 is affected, but the first load current I _o1 Control is not affected. In this case, since the decrease in the second load current I _o2 is compensated by the increase in the first load current I _o1 , the proportional relationship between the reference current Ir1 and the load current IL is maintained.

  In the configuration of FIG. 7, it is necessary to accurately match the ratio of the drain currents of the transistor (M4) 13 and the transistor (M10) 18 by the MOSFET, but the resistance of the second reference resistance element 3 and the first reference resistance element 1 This is effective when the value ratio R3: R1 is large and the source voltages of the transistors 12, 13, and 18 are low.

  As described above, according to the third embodiment, the ratio between the reference current and the load current can be accurately maintained even in a region where the current value is small, as in the first embodiment. Further, even in a region where the current value of the reference current is large, an error in the reference current can be suppressed, and the ratio between the reference current and the load current can be maintained with high accuracy.

(Various aspects of this embodiment)
Various aspects of the embodiment according to the present invention include the following.

  A first detection resistance element and a second detection resistance element for detecting a load current flowing in the LED, and a first current control element and a second current control element for controlling the load current, The first current control element and the second current control element are connected in parallel between the LED and the ground, and the first current control element, the first detection resistance element, the second current control element, A current control element and the second detection resistance element are each connected in series, and the first detection resistance element and the second detection resistance element are connected in series between the LED and the ground, A reference current generation unit configured to generate a reference current for controlling the load current; and a first current control element configured according to a ratio between the reference current and a load current detected by the first detection resistance element. The first to control the operation An operation control circuit; a second operation control circuit that controls an operation of the second current control element in accordance with a ratio of the reference current to a load current detected by the second detection resistance element; and the reference A drive circuit control unit that controls the first operation control circuit and the second operation control circuit in accordance with a magnitude of a current, wherein the drive circuit control unit has a reference current magnitude of An LED drive circuit that stops the operation of the first current control element when the value is less than a predetermined value of 1.

  In the LED driving circuit, the reference current generator includes a reference current source that outputs the reference current, and a first reference resistance element and a second reference resistance element that generate a voltage proportional to the reference current. The first reference resistance element and the second reference resistance element are connected in series between the reference current source and the ground, and the first operation control circuit includes A voltage based on a difference between voltages generated in the first detection resistance element and the first reference resistance element is output to the first current control element, and the second operation control circuit is configured to output the second detection resistance element. The LED drive circuit which outputs the voltage based on the difference of the voltage which each generate | occur | produces in a resistance element and a said 2nd reference resistance element to a said 2nd current control element.

  In the LED driving circuit, the reference current generation unit includes a first reference current source that outputs a first reference current as the reference current, and a second reference current that is proportional to the first reference current. A second reference current source that outputs a voltage, a first reference resistance element that generates a voltage proportional to the first reference current, and a second reference resistance that generates a voltage proportional to the second reference current And the second reference resistance element is connected between the second reference current source and the ground, and the first operation control circuit includes the first detection resistance element and the first detection resistance element. A voltage based on a difference in voltage generated in each of the first reference resistance elements is output to the first current control element, and the second operation control circuit includes the second detection resistance element and the second detection resistance element. The voltage based on the difference between the voltages generated in the reference resistance elements is And outputs the second current control element, LED driving circuit.

  In the above LED drive circuit, the drive circuit control unit includes a current detection circuit that detects the magnitude of the reference current, and when the magnitude of the reference current is less than the first predetermined value, When only the second current control element is operated and the magnitude of the reference current is not less than the first predetermined value, the first current control element is operated, and the magnitude of the reference current is the first current An LED driving circuit for stopping the operation of the second current control element when the second predetermined value is equal to or greater than a predetermined value of 1.

  In the above LED drive circuit, the drive circuit control unit includes a current detection circuit that detects the magnitude of the reference current, and a third predetermined value in which the magnitude of the reference current is equal to or greater than the first predetermined value. And a limiting circuit that limits a voltage generated in the second reference resistance element when the value becomes equal to or greater than the value.

  While various embodiments have been described above with reference to the drawings, it goes without saying that the present invention is not limited to such examples. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood. In addition, the constituent elements in the above embodiment may be arbitrarily combined without departing from the spirit of the present invention.

  INDUSTRIAL APPLICABILITY The present invention can be used for an LED drive circuit that adjusts the brightness of an LED by current control of a load current, and is particularly useful for an LED drive circuit that performs brightness adjustment at a low brightness.

1: First reference resistance element (R1)
2: First detection resistance element (R2)
3: Second reference resistance element (R3)
4: Second detection resistance element (R4)
5, 6, 7, 8: resistance element 10: first current control element (M1)
11: Second current control element (M2)
12, 13, 14, 18: transistor 15, 16, 17: switch element 22: first amplifier (AMP1)
23: Second amplifier (AMP2)
24: First reference current source (Ir1)
25: Second reference current source (Ir2)
30: Diode (D1)
31: LED
32, 35: Current detection circuit 33: Voltage source (V1)
34: Clamp circuit

Claims (4)

A first detection resistance element and a second detection resistance element for detecting a load current flowing in the LED;
A first current control element and a second current control element for controlling the load current,
The first current control element and the second current control element are connected in parallel between the LED and the ground, and the first current control element, the first detection resistance element, the second current control element, A current control element and the second detection resistance element are each connected in series, and the first detection resistance element and the second detection resistance element are connected in series between the LED and the ground,
A reference current source that outputs a reference current for controlling the load current ;
A first reference resistance element and a second reference resistance element that generate a voltage proportional to the reference current;
The first reference resistance element and the second reference resistance element are connected in series between the reference current source and ground;
The first current control element controls the operation of the first current control element according to the difference between the voltage generated in the first reference resistance element and the voltage proportional to the load current generated in the first detection resistance element . An operation control circuit of
A second control circuit configured to control an operation of the second current control element according to a difference between a voltage generated in the second reference resistance element and a voltage proportional to the load current generated in the second detection resistance element; An operation control circuit of
A drive circuit control unit that controls the first operation control circuit and the second operation control circuit according to the magnitude of the reference current;
The drive circuit control unit turns on the second operation control circuit to operate the second current control element when the magnitude of the reference current is less than a first predetermined value , and operates the second current control element. An LED drive circuit that turns off the operation control circuit to stop the operation of the first current control element. A first detection resistance element and a second detection resistance element for detecting a load current flowing in the LED;
A first current control element and a second current control element for controlling the load current,
The first current control element and the second current control element are connected in parallel between the LED and the ground, and the first current control element, the first detection resistance element, the second current control element, A current control element and the second detection resistance element are each connected in series, and the first detection resistance element and the second detection resistance element are connected in series between the LED and the ground,
A first reference current source that outputs a first reference current as a reference current for controlling the load current, and a second reference current source that outputs a second reference current proportional to the first reference current When,
A first reference resistance element that generates a voltage proportional to the first reference current; and a second reference resistance element that generates a voltage proportional to the second reference current;
The second reference resistive element is connected between the second reference current source and ground;
The first current control element controls the operation of the first current control element according to the difference between the voltage generated in the first reference resistance element and the voltage proportional to the load current generated in the first detection resistance element . An operation control circuit of
A second control circuit configured to control an operation of the second current control element according to a difference between a voltage generated in the second reference resistance element and a voltage proportional to the load current generated in the second detection resistance element; An operation control circuit of
A drive circuit control unit that controls the first operation control circuit and the second operation control circuit according to the magnitude of the reference current;
The drive circuit control unit turns on the second operation control circuit to operate the second current control element when the magnitude of the reference current is less than a first predetermined value, and operates the second current control element. An LED drive circuit that turns off the operation control circuit to stop the operation of the first current control element . The LED driving circuit according to claim 1 or 2 ,
The drive circuit control unit includes a current detection circuit that detects the magnitude of the reference current,
When the magnitude of the reference current is less than the first predetermined value, only the second current control element is operated, and when the magnitude of the reference current is greater than or equal to the first predetermined value, LED driving that operates one current control element and stops the operation of the second current control element when the magnitude of the reference current is not less than a second predetermined value that is not less than the first predetermined value. circuit. The LED driving circuit according to claim 1 ,
The drive circuit control unit includes a current detection circuit that detects the magnitude of the reference current, and the first current when the magnitude of the reference current is equal to or greater than a third predetermined value that is equal to or greater than the first predetermined value. And a limiting circuit that limits a voltage generated in the two reference resistance elements.

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