JP3800115B2 - Load drive circuit with overcurrent detection function - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a load drive circuit having a load current overcurrent detection function, and more particularly to a circuit technique suitable for load overcurrent detection that generates an inrush current when energization is started.
[0002]
[Prior art]
A load drive circuit using a power MOSFET, a power transistor, an IGBT, or the like as a load current switching element is often provided with an overcurrent detection circuit for protecting the switching element from an excessive current due to a load short circuit or the like. This overcurrent detection is usually performed by converting the load current into a voltage using a sense resistor and comparing the detected voltage with a threshold voltage for overcurrent determination. However, when the load is an incandescent lamp or a solenoid, a large inrush current flows at the start of energization. In such a case, if the threshold voltage is set on the basis of the load current in a steady state, the inrush current at the start of energization is determined as an overcurrent, which is inconvenient.
[0003]
One method for avoiding this inconvenience is that overcurrent detection is not performed during a period when an inrush current flows immediately after the start of energization. However, in this method, when the load is short-circuited before the start of energization, the switching element is destroyed. As a method for improving this, as shown in FIG. 9, there is a method of setting the overcurrent detection level high immediately after the start of energization and switching the overcurrent detection level to a low value in accordance with the time when the inrush current decreases.
[0004]
FIG. 10 is an example of a load driving circuit configured to realize such a method. In FIG. 10, the NMOS switching elements Q100 and Q101 connected in parallel open and close the current flowing through the load 101 according to the energization command signal applied to the commonly connected gate terminals 100. In this case, the element area of the switching element Q100 is formed larger than Q101. Then, most of the load current flows through the switching element Q100, and only a part of the load current is shunted toward Q101. Since the shunt ratio is a constant value approximately proportional to the area of the element, when the current flowing through the switching element Q101 is converted into a voltage by the sense resistor R100 connected to the drain side, a voltage Vl proportional to the load current is obtained. .
[0005]
On the other hand, the threshold voltage Vr for determining the overcurrent detection level is generated by dividing the voltage Vdd by the resistor R102 and a resistance value formed by a resistor group including resistors R103 and R104a connected to the ground side. In order to change the threshold voltage Vr, the switching element Q102a or the like switches the resistor 104a or the like according to the elapsed time from the start of energization, and a stepped overcurrent detection level (threshold value as shown in FIG. 9). Voltage Vr).
[0006]
[Problems to be solved by the invention]
However, in this circuit system, although the overcurrent detection level can be switched stepwise, it cannot be continuously changed in accordance with the inrush current waveform. In order to obtain a continuous curve, it is necessary to finely switch the voltage dividing ratio. To that end, the number N of voltage dividing resistors and switching elements must be increased. This increases the number of parts and complicates the timing signal generation circuit for switching. Further, when these circuits are formed on the same semiconductor substrate for integration, there is a problem that the substrate area increases.
[0007]
An object of the present invention is to solve the above problems, and more specifically, an overcurrent detection level can be easily set and changed without impairing the original overcurrent detection function. It is an object of the present invention to provide a load drive circuit having a current detection function and a load drive circuit having an overcurrent detection function that does not detect an inrush current at the start of energization as an overcurrent.
[0008]
[Means for Solving the Problems]
  The load driving circuit according to claim 1 for solving the above-described problem includes a first current source,A load driving circuit comprising first and second current mirror circuits, first and second NMOS transistors, first and second resistors, a comparator, and a timing signal generation circuit, The timing signal generation circuit receives a load drive signal input from the outside, sends a current value command signal for outputting a high current to the first current source for a predetermined time, and is constant from the rise of the current value command signal. The energization command signal is sent to the first and second NMOS transistors with a delay in time, and the first current source does not receive the current value command signal for outputting the high current. The first current mirror circuit is configured to output a predetermined constant current during the interval, and output a predetermined high current while receiving the current value command signal. The first current mirror circuit includes the first current source. The second current mirror circuit is configured to output a current obtained by multiplying the output current of the first current mirror circuit by a constant factor. The first and second NMOS transistors are connected to a common gate and a common source, and open and close a current of a load connected to the common source by an energization command signal output from the timing signal generation circuit. The first resistor is connected to the output of the second current mirror circuit and has a voltage proportional to the output current of the second current mirror circuit across the both ends. The second resistor is connected to the drain of the second NMOS transistor and is connected between both ends of the second NMOS transistor. The comparator is configured to generate a voltage proportional to the flowing current, and the comparator outputs an overcurrent signal when the voltage across the second resistor is greater than the voltage across the first resistor. The load driving circuit is configured to be configured as described above.
[0009]
  Such a load driving circuit raises the overcurrent detection threshold value during a period when a normal inrush current flows through the load, so that a normal inrush current is not erroneously detected as an overcurrent. In addition, since a configuration is made such that an energization command signal for driving the load is sent after a certain time delay after sending a command signal for increasing the overcurrent detection threshold, the threshold is already reached when the inrush current starts to flow. The value is high. If the energization command signal and the command signal for raising the threshold value are output at the same time, an overcurrent may be erroneously detected at the start of the inrush current due to variations in the circuit delay time. Since the command signal for increasing the value is preceded, such erroneous detection can be prevented. Further, the overcurrent detection threshold value during the period in which the load is not driven is maintained at, for example, a steady load current or higher. Therefore, it is possible to prevent the overcurrent detection signal from being output due to noise or the like during a period when the load current is not flowing.
[0010]
  The load driving circuit according to claim 2,The second current mirror circuit in the configuration of claim 1 is omitted, and the output current of the first current mirror circuit is immediately passed through the first resistor. The load driving start timing and the overcurrent detection threshold when the load is not driven are the same as in the configuration of the first aspect. Therefore, the same effect as the load drive circuit according to the first aspect can be obtained.
[0011]
  The load driving circuit according to claim 3 is the load driving circuit according to claim 1 or 2, wherein the first current source does not receive a current value command signal for outputting the high current. When a predetermined current is output and a current value command signal is received, a current pulse having a waveform similar to the impulse response waveform of the first-order lag circuit is superimposed and output from the rising edge of the signal. The load driving circuit is configured to be configured as described above.
[0012]
  The load drive circuit of the present configuration is configured so that the overcurrent detection threshold value becomes a value obtained by adding a substantially constant value to the normal inrush current to the load. The current waveform when the source outputs a high current is similar to the impulse response waveform of the first-order lag circuit. The load driving start timing and the overcurrent detection threshold value when the load is not driven are the same as those of the first and second aspects. With such a configuration, the difference between the overcurrent detection threshold value and the normal inrush current becomes a value close to a constant value, and the effect of improving the overcurrent detection accuracy is achieved.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 is a block diagram showing the configuration of the load drive circuit according to the first embodiment of the present invention.
In FIG. 1, the current source 1 has an output current that can be varied by an external signal. However, when the overcurrent detection level may be a constant value, it may be a fixed output current source. The output current Io of the first current source 1 is given as an input current to the second current source 2. The second current source 2 outputs a current a · Io obtained by multiplying the input current by a constant ratio a. This output current is input to the first voltage generating means 3. The first voltage generating means 3 generates a voltage proportional to the input current, and as a result, a voltage Vr proportional to the output current of the first current source 1 appears in the output. This voltage Vr is input to the voltage comparison means 9 as a threshold voltage Vr for determining the overcurrent level.
[0014]
On the other hand, the load 4 is supplied with a current from the power source Vdd, and the load current is opened and closed by first and second switching elements 5 and 6 connected in parallel that operate according to an energization command signal applied to the input terminal 7. The That is, the switching elements 5 and 6 constitute load driving means. As the switching elements 5 and 6, a power MOSFET, a power transistor, an IGBT, or the like can be used. In addition, the switching elements 5 and 6 are formed so that when a load current is passed, the load current is shared at a constant ratio. Such a current sharing method can be realized by using switching elements having different element areas. Alternatively, the switching elements 5 and 6 are formed as one switching element on the same semiconductor substrate, and the output current junction of the load current is divided into two junctions having a constant ratio area, so-called switching elements with sense terminals Can also be realized.
[0015]
The output current of the second switching element 6 is converted into a voltage Vl proportional to the current value by the second voltage generating means 8. This voltage Vl is proportional to the current flowing through the load 4. The voltage Vl proportional to the load current and the aforementioned threshold voltage Vr are compared by the voltage comparison means 9, and if it is determined that the voltage Vl is greater than the voltage Vr, an overcurrent output signal is output. That is, the circuit configured by the block diagram of FIG. 1 has a function of detecting an overcurrent of the load current at the same time as driving the load.
[0016]
In the conventional circuit of FIG. 10 described above, the threshold voltage Vr that determines the overcurrent detection level is generated by dividing the reference voltage Vdd with a resistor. In order to change the threshold voltage Vr by this circuit method, it is necessary to change the value of the voltage dividing resistor. However, since it is generally not easy to change the resistance value continuously, as shown in the example of FIG. There is no choice but to change it in steps.
[0017]
On the other hand, in the case of the present embodiment, a method is employed in which a threshold voltage Vr proportional to the output current of the first current source 1 is generated. Therefore, if the output current of the first current source 1 can be continuously changed, the threshold voltage Vr continuously changes. Here, various current source circuit systems have been devised, and it is not difficult to vary the output current by an external signal.
[0018]
For example, FIG. 2 is a simple circuit example of such a current source with variable output current, and this current source is composed of only two components, an NPN transistor Q1 and a resistor R1 connected to its emitter. When the voltage applied to the base is Vin and the base-emitter voltage is Vbe, the collector current Iout becomes a constant value calculated by the following equation (1).
Iout = (Vin−Vbe) / R1 (1)
That is, the circuit of FIG. 2 is a current source whose output current is determined by the voltage Vin applied to the base from the outside. Therefore, the output current value can be easily set or changed by changing the voltage Vin. Further, the output current Iout can be continuously changed by continuously changing the voltage Vin.
As described above, according to the circuit configuration of the present embodiment shown in the block diagram of FIG. 1, the overcurrent detection level can be easily set and changed, and the set value can be easily changed continuously.
[0019]
In the block diagram of FIG. 1, the second current source 2 is provided after the first current source 1, and the output current of the first current source 1 is supplied to the first voltage generating means 3 after being multiplied by a certain factor. Thus, the threshold voltage Vr is generated. For this reason, the maximum value of the output current of the first current source 1 (the output current value corresponding to the maximum overcurrent detection level) does not take the current value required by the first voltage generating unit 3 into consideration. You can choose quite freely. This means that there are less restrictions on the circuit design of the first current source 1, and the circuit design is facilitated. Furthermore, in the present embodiment, an electrical signal that determines the overcurrent detection level is generated by the first current source 1 in the form of a current signal, and is transmitted to the first voltage generation means 3 as the current signal. Therefore, there is an advantage that it is less affected by noise at the generation and transmission stages of signals, and is less affected by fluctuations in the power supply voltage Vcc.
[0020]
FIG. 3 is an example of a circuit configuration embodying the block diagram of FIG. The first current source 10 corresponds to the first current source 1 of FIG. 1 and is a power source whose output is variable by a current value command signal from the outside. However, when the overcurrent detection level may be a constant value, a fixed output power source may be used. The output terminal 12 of the current source 10 is connected to the current input terminal 13 of the current mirror circuit 11, and the output current Isa of the current source 10 is given as the input current of the current mirror circuit 11.
[0021]
The current mirror circuit 11 corresponds to the second current source 2 of FIG. 1, and is composed of PNP transistors Q2, Q3, Q4 and resistors R2, R3. In general, a current mirror circuit is a circuit that uses the characteristic that the magnitudes of collector currents of two transistors whose base terminals are connected in common are the same as each other like a mirror. In the case of the current mirror circuit 11, resistors R2 and R3 are connected to the emitter sides of the transistors Q2 and Q3, and the output current Isb from the current output terminal 14 has a resistance value ratio of R2: R3 = a: If it is 1, it becomes as follows.
Isb = a ・ Isa (2)
That is, an output current Isb obtained by multiplying the input current Isa by a constant factor is obtained. The transistor Q4 is for increasing the accuracy of the mirror ratio. If the accuracy is not so required, Q4 may be removed and the base and collector of the transistor Q2 may be short-circuited instead.
[0022]
The output current Isb of the current mirror circuit 11 flows through the first resistor R4 to the ground terminal, and generates the voltage Vr at the non-ground side terminal of the resistor R4. That is, the resistor R4 corresponds to the first voltage generating means 3 in FIG. 1, and the output voltage Vr is as follows.
Vr = a · Isa · R4 (3)
Since the voltage Vr is proportional to Isa, Isa is set so that the voltage Vr becomes a threshold voltage for determining the overcurrent level.
[0023]
On the other hand, the load 15 is driven by the first and second NMOS transistors Q5 and Q6. Q5 and Q6 correspond to the first and second switching elements 5 and 6 in FIG. 1, respectively. The transistors Q5 and Q6 are connected to a common gate and a common drain. Since the value of the sense resistor R5 is small, the transistors Q5 and Q6 are effectively connected in parallel. The transistors Q5 and Q6 operate according to an energization command signal applied to the commonly connected gate input terminal 16, and open and close the current flowing through the load 15.
[0024]
As described in the description of FIG. 1, the transistors Q5 and Q6 are formed so as to share a current flowing through the load 15 at a constant ratio when both are in a conductive state. Therefore, the voltage Vl proportional to the load current can be obtained by passing the current flowing through the transistor Q6 through the second sensing resistor R5 connected to the source side. That is, the second resistor R5 corresponds to the second voltage generating means 8 in FIG.
[0025]
The voltage Vl proportional to the load current and the threshold voltage Vr are compared by the comparator COMP1, and an overcurrent output signal is generated. That is, the comparator COMP1 corresponds to the voltage comparison means 9 in FIG.
The circuit of FIG. 3 is an example in which the block diagram of FIG. 1 is embodied, and has the same effect as described in the description of the block diagram of FIG.
[0026]
FIG. 4 is an example of another circuit configuration that embodies the block diagram of FIG. 4, the same reference numerals are given to the same or corresponding parts as in FIG. The circuit configuration of FIG. 4 is greatly different from the circuit configuration of FIG. 3 in that the current mirror circuit 11 portion of FIG. 3 is connected in cascade with the first current mirror circuit 11 and the second current mirror circuit 17 in FIG. The two current mirror circuits are replaced.
[0027]
As a result, the output current of the first current mirror circuit 11 becomes the input current of the second current mirror circuit 17, and the output current of the second current mirror circuit 17 flows through the second resistor R4. Yes. In addition, the first and second NMOS transistors Q5 and Q6 as switching elements are connected in common to the source, and the load 15 is connected between the commonly connected source and the ground terminal, and the second resistor R5. Is different in that it is connected between the drain of the second transistor Q6 and the power supply Vdd. The comparator COMP1 compares the threshold voltage Vr appearing at both ends of the first resistor 4 with the voltage Vl proportional to the load current appearing at both ends of the second resistor R2, as in FIG. Output. Since one ends of the resistors R4 and R5 are connected to the power supply Vdd instead of the reference potential GND, the connection to the input terminal of the comparator COMP1 is opposite to that in FIG.
[0028]
The circuit of FIG. 4 is also an example in which the block diagram of FIG. 1 is embodied, and thus has the same effect as described in the description of the block diagram of FIG. In the case of FIG. 4, since one end of the load 15 is connected to the reference potential GND, there is an advantage that a common reference potential wiring can be used for wiring to the load 15.
[0029]
(Second Embodiment)
This embodiment is an embodiment corresponding to a load through which an inrush current flows when energization is started, such as an incandescent lamp, and its circuit configuration is shown in FIG. This circuit is a load driving circuit obtained by adding a timing signal generating circuit 18 to the circuit configuration of FIG. 4 described above. The operation of the timing signal generation circuit 18 and the overall overcurrent detection operation will be described with reference to the timing chart of each part waveform shown in FIG.
[0030]
The timing signal generation circuit 18 receives an external load drive signal as an input, sends an energization command signal to the transistors Q5 and Q6 that open and close the load current, and detects an overcurrent to the first current source 10. An operation of sending a current value command signal which is a command signal for determining the level is performed. However, in order to prevent an overcurrent detection signal from being output due to noise or the like during a period when the load current is not flowing, the timing signal generation circuit 18 also includes the current source 10 even during a period when the load drive signal signal is not received. On the other hand, a current value command signal is output so as to maintain the overcurrent detection level at or above the load current at the steady state.
[0031]
Then, at the same time as receiving the load drive signal from the outside, as shown in FIG. 6B, a current value command signal increased so that the overcurrent detection level becomes equal to or higher than the inrush current of the load is sent to the current source 10. Next, an energization command signal for turning on the transistors Q5 and Q6 is sent out as shown in FIG. As a result, a load current with an inrush current as shown in FIG. 6 (e) flows, but the overcurrent detection level is increased to a value higher than the inrush current by the previous current value command signal as shown in FIG. 6 (d). Therefore, it is not judged as overcurrent. Since the inrush current rapidly decreases with time and decreases to a steady-state current value, the timing signal generation circuit 18 uses a built-in timer to detect the overcurrent detection level after a certain time from receiving the load drive signal. The level of the current value command signal is lowered so as to decrease to a value corresponding to the constant load current.
[0032]
Thus, since the overcurrent detection level is increased only during the period when the inrush current flows, the inrush current is prevented from being erroneously determined as an overcurrent. In a steady state after the inrush current period has elapsed, overcurrent detection is performed with an overcurrent detection level that matches the steady load current. In this method, the overcurrent detection operation is not stopped even during the inrush current period, so if a current larger than the inrush current flows during this period due to a load short circuit, The overcurrent detection signal is output after the determination.
[0033]
When a large current such as an inrush current flows, the current sharing ratio of the transistors Q5 and Q6 deviates from the sharing ratio at the steady load current, and the transistor Q6 bearing a small current is higher than the steady state. Since the current of the sharing ratio tends to flow, it is desirable to determine the overcurrent detection level in the period during which the inrush current flows in consideration of this point.
[0034]
(Third embodiment)
This embodiment is also an embodiment corresponding to a load in which an inrush current flows at the start of energization, such as an incandescent lamp, but has an overcurrent detection level that continuously changes with a curve approximating the inrush current waveform. The present invention relates to a load driving circuit having a current detection function. In the load driving circuit of the present embodiment shown in FIG. 7, the timing signal generating circuit 18 is added to the circuit of FIG. 4 described above, and the first current source 10 is a current source as shown by 19 in the figure. It is replaced with a circuit.
[0035]
The timing signal generation circuit 18 receives an external load drive signal and generates an overcurrent detection level approximating an inrush current waveform and an operation of sending an energization command signal to the transistors Q5 and Q6 that open and close the load current. For this purpose, an operation for sending a pulse signal as a trigger to the current source 19 is performed.
[0036]
The output section of the current source circuit 19 is composed of a transistor Q9 and a resistor R8, which has the same configuration as that shown in FIG. That is, the output current Isa is a constant value determined by the base voltage of the transistor Q9. This circuit is an emitter follower circuit and has a very high input impedance. For this reason, most of the current flowing through the emitter-side resistor R11 of the transistor Q10 flows through the transistor Q10 to the ground terminal.
[0037]
When no input signal is applied to the current source circuit 19, the base-emitter junction of the transistor Q10 is forward-biased through the power supply voltage Vcc, the resistor R11, and the resistor R10, and the base current flows. If the base-emitter forward voltages of the transistors Q9 and Q10 are equal and the current amplification factor is sufficiently high, the base potential of the transistor Q10 and the emitter potential of the transistor Q9 are the same potential, so the output of the current source circuit 19 The current Isa is expressed as follows when the base potential of the transistor Q10 is Vb.
Isa = Vb / R8 (4) Formula
That is, the output current Isa of the current source circuit 19 is proportional to the base potential Vb of the transistor Q10, in other words, the charging voltage of the capacitor C1 connected between the base of the transistor Q10 and the ground terminal.
[0038]
In the case of this embodiment as well, it is necessary to maintain the overcurrent detection level at a value higher than zero current so that the overcurrent detection signal is not output due to noise or the like during a period when the load current is not flowing. In the case of this circuit, even when there is no input signal of the current source circuit 19, the current calculated by the above equation (4) is output, and the overcurrent detection level determined from this current value is higher than zero current. Therefore, no malfunction occurs due to noise or the like.
[0039]
In a state where the steady load current flows after the inrush current disappears, the overcurrent detection level needs to be set to a current level that is larger than the steady load current by a certain rate. The adjustment of the output current Isa of the current source circuit 19 necessary for maintaining the overcurrent detection level at such a value can be performed by adjusting the resistors R8, R10, and R11. This may be done by outputting a constant current value setting signal from the circuit 18 and adjusting the base potential Vb of the transistor Q10.
[0040]
Next, the operation of overcurrent detection when a load drive signal is input from the outside will be described with reference to the timing chart of each part waveform shown in FIG.
Immediately after the load drive signal is input to the timing signal generation circuit 18, an impulse voltage is sent as a current value command signal to the current source circuit 19. Impulse is defined as a waveform having a very high peak value, a very short duration, and a waveform area equal to 1, but it is impossible to actually realize such a waveform in an electric circuit. . Therefore, instead, a pulse voltage having a constant peak value and a short width (duration) as shown in FIG. 8B is generated by the timing signal generation circuit 18 and applied to the input terminal 20 of the current source circuit 19. .
[0041]
The applied pulse voltage passes through the series circuit of the diode D1 and the resistor R9, and charges the capacitor C1 connected in parallel to the resistor R10. Here, since the resistance value of the resistor R9 is very low, a current close to the impulse waveform flows into the capacitor C1, and the capacitor C1 is instantaneously charged to the peak value of the input pulse voltage.
[0042]
When the application pulse ends, the charge charged in the capacitor C1 starts to discharge through the resistor R10, and the charge voltage decays with a time constant R10 · C1 up to the charge voltage before applying the pulse while drawing an exponential function curve. . Such a waveform is called an impulse response waveform of the first-order lag circuit. Since this impulse response voltage waveform is applied as the base voltage Vb of the transistor Q10, the overcurrent detection level is changed to the overcurrent detection level at the steady state as shown in FIG. It changes continuously by drawing a curve with a superimposed waveform.
[0043]
On the other hand, the timing signal generating circuit 18 sends an energization command signal to the transistors Q5 and Q6. This command signal is sent out at the same time as the end of the current command signal pulse or at a timing that starts just before the end. The energization command signal causes the transistors Q5 and Q6 to conduct, and a load current with an inrush current as shown in FIG. 8E flows. This inrush current waveform also exhibits a waveform similar to the impulse response waveform in the case of an incandescent lamp or a solenoid.
[0044]
By the operation of the circuit as described above, the overcurrent detection level and the load current change in a waveform as shown in FIGS. 8D and 8E. That is, the overcurrent detection level changes while drawing a continuous curve while maintaining a current level somewhat higher than the inrush current, in accordance with the magnitude of the inrush current. Therefore, it is possible to prevent the inrush current from being erroneously determined as an overcurrent. In a steady state after the inrush current period has elapsed, overcurrent detection is performed at an overcurrent detection level that matches the steady load current. Further, since the overcurrent detection is performed while the inrush current flows, an overcurrent detection signal is output when an abnormal large current flows due to a load short circuit or the like during this time.
[0045]
As mentioned above, although embodiment of the invention made | formed by this inventor was concretely demonstrated based on drawing, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the summary. Needless to say. For example, the transistors Q5 and Q6 can be IGBTs, power transistors, or PMOS transistors having drains connected in common. Further, as the transistor in the current source circuit, a MOSFET can be used instead of the bipolar transistor.
[0046]
As an embodiment of the present invention, when an overcurrent detection signal is output, it is simple to latch the signal with a latch circuit and turn off the load driving switching element with the latched signal. By configuring the load driving circuit, it is possible to easily configure a load driving circuit having a function of protecting the load driving switching element.
[Brief description of the drawings]
FIG. 1 is a functional block diagram of a load driving circuit with an overcurrent detection function according to a first embodiment of the present invention.
FIG. 2 is an electric circuit diagram showing an example of a current source circuit.
FIG. 3 is an electric circuit diagram for realizing the functional block diagram of FIG.
4 is another electrical circuit diagram for realizing the functional block diagram of FIG.
FIG. 5 is a view corresponding to FIG. 3, showing a second embodiment of the present invention.
6 is a timing chart of the circuit shown in FIG.
FIG. 7 is a view corresponding to FIG. 3, showing a third embodiment of the present invention.
8 is a timing chart of the circuit shown in FIG.
FIG. 9 is a timing chart of a load driving circuit showing the prior art.
FIG. 10 is an electric circuit diagram of a load driving circuit.
[Explanation of symbols]
In the drawings, 1 is a first current source, 2 is a second current source, 3 is a first voltage generating means, 4 is a load, 5 is a first switching element, 6 is a second switching element, and 8 is Second voltage generation means, 9 is voltage comparison means, 10 is a first current source, 11 is a first current mirror circuit, 15 is a load, 17 is a second current mirror circuit, 18 is a timing signal generation circuit, Q5 is a first NMOS transistor, Q6 is a second NMOS transistor, R4 is a first resistor, R5 is a second resistor, and COMP1 is a comparator.

Claims (3)

A load comprising a first current source, first and second current mirror circuits, first and second NMOS transistors, first and second resistors, a comparator, and a timing signal generation circuit A drive circuit,
The timing signal generation circuit receives a load drive signal input from the outside, sends a current value command signal for outputting a high current for a predetermined time to the first current source, and rises the current value command signal. Is configured to send an energization command signal to the first and second NMOS transistors after a certain delay from
The first current source outputs a predetermined constant current while not receiving the current value command signal for outputting the high current, and outputs a predetermined high current while receiving the current value command signal. Is configured to
The first current mirror circuit is configured to output a current obtained by multiplying an output current of the first current source by a constant factor.
The second current mirror circuit is configured to output a current obtained by multiplying the output current of the first current mirror circuit by a constant factor.
The first and second NMOS transistors are connected to a common gate and a common source, and open and close a load current connected to the common source by an energization command signal output from the timing signal generation circuit. It is configured to share the current at a certain ratio,
The first resistor is connected to the output of the second current mirror circuit and is configured to generate a voltage proportional to the output current of the second current mirror circuit between both ends.
The second resistor is connected to the drain of the second NMOS transistor and is configured to generate a voltage proportional to the current flowing through the second NMOS transistor between both ends.
The load driving circuit, wherein the comparator is configured to output an overcurrent signal when a voltage across the second resistor is larger than a voltage across the first resistor. . A load driving circuit including a first current source, a first current mirror circuit, first and second NMOS transistors, first and second resistors, a comparator, and a timing signal generation circuit. There,
The timing signal generation circuit receives a load drive signal input from the outside, sends a current value command signal for outputting a high current for a predetermined time to the first current source, and rises the current value command signal. Is configured to send an energization command signal to the first and second NMOS transistors after a certain delay from
The first current source outputs a predetermined constant current while not receiving the current value command signal for outputting the high current, and outputs a predetermined high current while receiving the current value command signal. Is configured to
The first current mirror circuit is configured to output a current obtained by multiplying an output current of the first current source by a constant factor .
The first and second NMOS transistors are connected in common to the gate and the drain, and open and close the current of the load connected to the common drain in response to an energization command signal output from the timing signal generation circuit. Is configured to share a certain ratio ,
The first resistor is configured to generate a voltage proportional to the output current of the first of the connected current mirror circuits of the first across the output of the current mirror circuit,
The second resistor is connected to the source of the second NMOS transistor and is configured to generate a voltage proportional to the current flowing through the second NMOS transistor between both ends.
The load driving circuit, wherein the comparator is configured to output an overcurrent signal when a voltage across the second resistor is larger than a voltage across the first resistor. . 3. The load driving circuit according to claim 1 , wherein the first current source outputs a predetermined constant current while the current value command signal for outputting the high current is not received. When a command signal is received, a current pulse having a waveform similar to the impulse response waveform of the first-order lag circuit is output and superimposed on the constant current from the rising edge of the signal. Load drive circuit.

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