This application claims the benefit of foreign priority of Japanese application 2013-084019, filed Apr. 12, 2013, the disclosure of which incorporated herein by reference.
1. Field of the Invention
The present invention relates to a regulator circuit used in a power conversion device such as an internal combustion engine ignition device, and to a semiconductor integrated circuit device forming the regulator circuit. More particularly, the invention relates to a regulator circuit wherein it is possible to output a voltage which enables a load circuit (one or more circuits serving as a load of the regulator circuit) to operate normally despite a momentary interruption or momentary drop of an external power supply voltage, and to a semiconductor integrated circuit device forming the regulator circuit.
2. Description of the Prior Art
Of the reference signs in
When the capacitor is low in capacitance, the discharge is carried out so that the VREG follows the drop of the VB. When the VB drops drastically, the VREG also drops drastically, and a minimum voltage VREG2 of the VREG reaches 0V. When a VREG1 shown by the broken line is set to be a voltage which enables the load circuit 70 to operate normally, it is difficult for the load circuit 70 to operate normally at a point at which VREG2<VREG1. The load circuit 70 has a logic circuit incorporated therein and, for example, a latch circuit configured of the logic circuit cannot maintain a normal state, thus causing malfunction such as latch release.
The regulator circuit 500 starts operating, and when the VB rises gradually from 0V, the VREG rises following the VB. Because of this, the VB and VREG rise in a relationship of VREG=VB. VREG=VREG0 at a point at which the VB reaches the VREG0, and the VREG is the VREG0 and a constant voltage in a condition in which VB>VREG0. Normally, the regulator circuit 500 operates at the VREG0. Herein, for example, the circle indicates an operating point.
Meanwhile, when the VB drops to 0V from a voltage higher than the VREG0 in a stop and transitional state of the regulator circuit 500, VREG=VREG0 when VB≧VREG0, while VREG=VB in the range of VREG0>VB=0V, and the VREG drops to 0V following the VB.
Also, it is disclosed in JP-A-59-96828 (FIG. 2) that, in a parallel redundant system direct current power supply device including a backflow prevention diode on the output side, by adopting a configuration wherein a dummy resistor is used only when necessary, it is possible to reliably carry out the selection of a defective device, and thus possible to contribute to a loss reduction.
Also, the following is disclosed in JP-A-2004-129413 (FIG. 1). A charge pump circuit includes a voltage source, a boosting capacitor, a holding capacitor, and a diode provided so as to prevent a backflow of a discharge current of a capacitor charged by the voltage source, and reduce the output voltage of the charge pump circuit by the amount of forward voltage. The circuit outputs a voltage value greater than that of the output voltage of the voltage source by utilizing the action of charging the capacitors. The circuit also includes a correcting diode provided so as to increase the output voltage of the voltage source by the amount of forward voltage. This configuration prevents the output voltage of the charge pump circuit from being affected by the forward voltage of the diode.
It is disclosed in JP-A-2010-288444 (FIG. 1) to provide a gate drive device, which drives the gate of an active element with high input capacitance, such as an IGBT or MOSFET, including a semiconductor integrated circuit 4 having an internal power supply circuit which forms an internal power source based on an external power source supplied from an external power supply such as a battery. The semiconductor integrated circuit incorporates a voltage drop suppression circuit, and a drop of the internal power supply voltage of the internal power supply circuit to lower than a minimum operating voltage, and a sharp drop of voltage output to the gate, are suppressed by the voltage drop suppression circuit when an input external power supply voltage drops momentarily to lower than a minimum operating voltage. It is disclosed a gate drive device which can thereby suppress a fluctuation in the internal power supply voltage and output voltage while reducing the number of parts by omitting a bypass capacitor connected in parallel to the semiconductor integrated circuit. It is described that a ZD/R parallel circuit wherein a zener diode ZD and resistor R are connected in parallel to the internal power supply circuit is provided in the gate drive circuit. A description is given, in
However, with the regulator circuit 500 of
Also, the resistor 64 is necessary for supplying voltage to the load circuit 70 until a threshold voltage (of on the order of 0.6V) of the zener diode 61 is reached when the VB rises from 0V, as will be described hereafter. Next, a description will be given of an advantageous effect obtained by providing the ZD/R parallel circuit 60. The threshold voltage (=0.6V) of the zener diode 61 is a voltage when a forward voltage rises and a voltage affected by the diffusion potential of a pn junction.
Meanwhile, when the VB is momentarily interrupted, VB<VREG0, and VB=0V in an extreme case. At this time, electric charge within the load circuit 70 is discharged, and a reverse current tends to flow toward the VB terminal via the ZD/R parallel circuit 60 which is a backflow limiter circuit, but is blocked by the zener diode 61, meaning that the reverse current flows via the resistor 64. When the VB voltage<0, the reverse current flows from the GND into the resistor 64 via the body diodes of the series of currents. Consequently, when VB=0V, VREG=VREG2 rather than VREG=0. The VREG2 depends on the current flowing through the resistor 64.
By setting the VREG2 to be equal to or higher than a voltage VREG1) at which the resistor 64 is optimized to enable the load circuit 70 to operate normally, the load circuit 70 can maintain the operation normally even when there is a momentary voltage interruption or momentary voltage drop.
VREG=VREG0−Vp when VB≧VREG0. Also, VREG=VB−Vp when VB<VREG0. The drop rate of the VREG decreases when the VB is between the threshold voltage (0.6V) of the zener diode 61 and 0V. This is because a voltage (R×Ir1) generated in the resistor 64 is dominant when the Vp is between these voltages. The VREG is supplied to the load circuit 70. The circle in
That is, in the regulator circuit 600 shown in
Also, in JP-A-59-96828 (FIG. 2) and JP-A-2004-129413 (FIG. 1), a regulator output is stabilized toward a drop in the external power supply voltage to prevent malfunction of the load circuit, thus enabling a circuit operation even at the low external power supply voltage. Furthermore, no description is given of a regulator circuit wherein the VREG has no temperature dependence so that it is possible to supply a voltage which enables the load circuit to operate normally.
An object of the invention is to solve the heretofore described problems and provide a regulator circuit wherein it is possible to supply a voltage which enables a load circuit, which is a circuit or a plurality of circuits as a load of the regulator circuit, to operate normally even when an external power supply voltage is momentarily interrupted or drops momentarily, and an output voltage which enables the load circuit to operate normally with no temperature dependence, and a semiconductor integrated circuit device forming the regulator circuit.
In order to achieve the object, according to a first aspect of the invention, a regulator circuit, which lowers an external power supply voltage and supplies the voltage to a load circuit, includes an external power supply voltage terminal; a transistor connected to the external power supply voltage terminal; a first resistor connected to the transistor; a second resistor of which one end is connected to the first resistor and the other end is connected to a ground; an operational amplifier which controls the regulator circuit; and a reference voltage circuit connected to the positive terminal of the operational amplifier. A configuration is such that the negative terminal of the operational amplifier is connected to the connection point of the first resistor and second resistor, the output of the operational amplifier is connected to the gate of the transistor, the output terminal of the regulator circuit is connected to the connection point of the transistor and first resistor, and a backflow limiter circuit connected to and between the external power supply voltage terminal and the transistor is provided.
Also, according to a second aspect of the invention, in the regulator circuit according to the first aspect, it is preferable that the backflow limiter circuit is formed of a parallel circuit of a diode and resistor, or formed of the diode alone, and the anode of the diode is connected to the external power supply voltage terminal.
Also, according to a third aspect of the invention, in the regulator circuit of the second aspect, it is preferable that the diode is a pn diode, a zener diode, or a Schottky diode.
Also, according to a fourth aspect of the invention, in the regulator circuit of the first aspect, it is preferable that the transistor is an enhancement type or depression type n-channel MOSFET.
Also, according to a fifth aspect of the invention, in a semiconductor integrated circuit device, it is preferable that the regulator circuit according to any one of the first to fourth aspects and the load circuit are formed on the same semiconductor substrate.
In the invention, it is possible to provide a regulator circuit wherein it is possible to supply a voltage which enables load circuits to operate normally, even when an external power supply voltage is momentarily interrupted or drops momentarily, by providing a parallel circuit (ZD/R parallel circuit), formed of a backflow prevention diode and a resistor, between an external power supply voltage terminal and the high potential side of a transistor, and a semiconductor integrated circuit device forming the regulator circuit.
Furthermore, it is possible to provide a regulator circuit wherein an output voltage which enables a load circuit to operate normally has no temperature dependence, and a semiconductor integrated circuit device forming the regulator circuit.
A First Working Example of a Regulator Circuit According to the Present Invention
The regulator circuit 100 includes an operational amplifier 1, a reference voltage circuit 5 connected to a positive terminal 2 of the operational amplifier 1, an MOSFET 6, a gate 9 of which is connected to an output terminal 4 of the operational amplifier 1, and the ZD/R parallel circuit 10 to which are connected a drain 7 of the MOSFET 6 and a cathode 13 of the zener diode 11. The regulator circuit 100 includes an external power supply voltage terminal (VB terminal) connected to an anode 12 of the zener diode 11 of the ZD/R parallel circuit 10, a first resistor 15 connected to a source 8 of the MOSFET 6 (of an enhancement type n-channel type), and a second resistor 16 of which one end is connected to the first resistor 15 and the other end is connected to a ground GND. The regulator circuit 100 includes a load circuit 20, which is a circuit or a plurality of circuits as a load of the regulator circuit 100, connected to a first connection point 17 which is the connection point of the MOM-ET 6 source 8 and first resistor 15, and an output terminal 19 of the regulator circuit 100 connected to the first connection point 17. The connection point of the first resistor 15 and second resistor 16 forms a second connection point 18. A negative terminal 3 of the operational amplifier 1 and the second connection point 18 are connected together. The operational amplifier 1 is connected to a power supply VDD and the ground GND. The ZD/R parallel circuit 10 is a circuit wherein the zener diode 11 and resistor 14 are connected in parallel. Also, it is good to use a band gap reference circuit as the reference voltage circuit 5 because it has no temperature dependence. Also, an ordinary pn diode may be used in place of the zener diode 11. Next, a description will be given of a circuit operation.
a. An external power supply voltage VB is applied to the VB terminal from an unshown external power supply circuit such as a battery.
b. The MOSFET 6 is put into an on-state by operating the operational amplifier 1. The MOSFET 6 is already in the on-state when it is of a depression type.
c. A reference voltage VREF input into the positive terminal 2 of the operational amplifier 1 is reflected in the negative terminal 3, and a current Im flows from the VB terminal via the ZD/R parallel circuit 10, MOSFET 6, first resistor 15, and second resistor 16 to the ground GND so that the reflected VREF is the voltage of the second connection point 18 which is the connection point of the first resistor 15 and second resistor 16. At this time, the voltage of the first connection point 17 which is the connection point of the MOSFET 6 and first resistor 15, being ((the resistance value of the first resistor 15+the resistance value of the second resistor 16)÷the resistance value of the second resistor 16)×the value of the VREF, reaches a set voltage VREG0 of an output voltage VREG of the regulator circuit 100. The VREG is a constant voltage at VREG=VREG0 until the external power supply voltage VB drops to the VREG0. The VREG (=VREG0) is the power supply voltage of the load circuit 20, causing the load circuit 20 to operate normally.
When the regulator circuit 100 starts operating and the VB rises gradually from 0V, the VB rises while maintaining VREG=VB−Vp. VREG=VREG0 when VB≧VGRE0+Vp. The Vp is a drop voltage of the ZD/R parallel circuit 10.
Meanwhile, a description will be given of a case in which the VB drops to 0V from a voltage higher than VREG0+Vp in a stop and transitional state of the regulator circuit 100. VREG=VREG0 when VB≧VREG0+Vp, and in the range of VREG0+Vp>VB=0.6V, the VB drops to 0.6V while maintaining VREG=VB−Vp. The drop rate of the VREG decreases in the range of 0.6V>VB=0. This is because the Vp is lower than a threshold voltage Vth (=0.6V) of the zener diode 11 in this range, and a voltage generated in the resistor 14 (r×Ir: r is a resistance value, and Ir is a current) is dominant. The VREG is supplied to the load circuit 20. The circle in
When VB≧VREG0+Vp, VREG=VREG0, as shown in
As VREG=VB−Vp when VB<VREG0+Vp, as shown in
By adopting the configuration of the first working example, it is possible to supply the load circuit 20 with a voltage (≧VGRE1) which enables the load circuit 20 to operate normally even when the VB is momentarily interrupted or drops momentarily.
Furthermore, an excessive reverse current flowing back from the second resistor 16, the first resistor 15, and the body diodes within the load circuit 20 when the external power supply voltage VB is negative with respect to the ground GND (for example, when a negative surge voltage is applied) can be prevented by the ZD/R parallel circuit 10 from flowing to the VB terminal via the body diode of the MOSFET 6. Because of this, it does not happen that electric charge within the load circuit is discharged, that is, it is possible to prevent malfunction, provided that the momentary voltage drop is for a certain amount of time.
When VB<VREG0, a current flowing into (a current flowing back to) the VB terminal is only the leakage current from the zener diode 11, and it is possible to reduce the current flowing into the VB terminal by the amount of reverse current. However, as there is a kind of disadvantage to be described hereafter, use applications are limited.
Also, when the VB drops from a voltage higher than the VREG0 and becomes lower than the VREG0, the VREG starts dropping at a point at which VB=VREG0+Vp. In the ZD circuit 10a, as a current to which is added the current Ir which has flowed through the resistor 14 is flowing through the zener diode 11, a voltage drop Vd of the zener diode 11 increases, and the Vp increases. As a result of this, the VB at which the VREG starts dropping becomes higher. That is, the region of the VB in which VREG=VREG0 decreases.
As it is possible to make the threshold voltage Vth0 lower than 0.6V (reduce the Vth0 to, for example, a voltage of on the order of 0.4V) by replacing the zener diode 11 with a Schottky diode (SBD), it is possible to terminate the inconstant state, in which the external power supply voltage is rising, at a VB (of on the order to 0.4V) lower than in the previously described case. Also, it is possible to lower the VB at which the VREG starts dropping.
The load circuit 20 has an unshown logic circuit formed in various kinds of diffusion regions, and the load circuit 20 (control circuit 25 and current detection circuit 26) exchanges signals with the power switching element 41, as shown by dotted lines 43. The various kinds of diffusion regions are a well region, a source region, a drain region, and the like, for forming a MOSFET configuring the logic circuit. Also, the power supply wiring 42 and the wirings shown by the dotted lines 43 are formed from a conductive film, on the semiconductor substrate 40, via an insulating film.
Also, the zener diode 11 and resistor 14 are, for example, formed from a polysilicon film, on the semiconductor substrate 40, via an insulating film, or each formed of a diffusion region in the semiconductor substrate 40.
With the semiconductor integrated circuit device 40 forming the regulator circuit 100/200 of the invention, as the load circuit 20 uses the output voltage VREG of the regular circuit 100/200 as the internal power supply voltage, the load circuit 20 can maintain a normal operation even when the external power supply voltage VB is momentarily interrupted or drops momentarily, and it is possible to reliably carry out a stable drive, detection, and protection of the external power switching element 41 which carries out an exchange of signals with the semiconductor integrated circuit device 40.
Also, a comparatively stable output is possible even for a still longer momentary voltage drop time by utilizing electric charge, with which the gate of the power switching element 41 is charged, for a power supply to the internal circuits while completely suppressing the reverse current flowing when there is a momentary voltage drop by changing the position of the parallel circuit 10 to the drain side of the MOSFET 6.
Number | Date | Country | Kind |
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2013-084019 | Apr 2013 | JP | national |