JP2006053803A - Power supply circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply circuit which is integrated with an IC chip and has the number of parts reduced. <P>SOLUTION: A power supply circuit 50 is configured by mounting first and second linear regulators omitted in Figure, which have different output voltages, overcurrent protection circuits added to respective linear regulators, short-circuit detection circuits of output voltages of respective linear regulators, and reset circuits of loads to which output voltages of respective linear regulators are supplied, on an IC chip 2. Output voltages of respective linear regulators are inputted to inverted input terminals of a comparator 21 from (b) and (c). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power supply circuit in which a composite circuit having different functions, such as a regulator, an overcurrent protection circuit, and a reset circuit, is integrated into a one-chip IC chip.

  As the power supply circuit is made into an IC, a three-terminal regulator capable of obtaining various output voltages as a stabilized power supply is used in various fields. A digital home appliance or a personal computer (PC) peripheral device to which the output voltage of such a regulator is supplied requires a plurality of power supply voltages. In LSIs used for CPUs and DSPs, products that require a plurality of voltage power supplies from a conventional single voltage power supply have been increasing recently.

  For example, in the LSI, the power supply voltage supplied from the regulator is set to 5V or 3.3V to the I / O terminal to which the signal input / output voltage for the peripheral IC is supplied. The operating voltage (core voltage) of the internal circuit mounted on the IC chip of the LSI uses a voltage of 2.5V to 1.0V. Therefore, the LSI is supplied with a plurality of voltages having different voltage values from the regulator.

  As described above, the voltage supplied to the I / O terminal of the IC chip in the LSI and the internal voltage of the IC chip are different from each other. (1) Due to the evolution of the IC manufacturing process, the withstand voltage of the internal circuit is lowered. It was. (2) This is based on the reason that the operating voltage of the IC internal circuit is lowered in order to reduce the power consumption of the entire IC.

  In general, in a power supply circuit, an overcurrent protection circuit is provided in order to prevent a circuit element from being damaged due to a short circuit or an overcurrent of an output supply line. Patent Document 1 describes that an overcurrent protection circuit is connected to a MOS-FET used in a ringing choke converter, and the MOS-FET is stopped when an overcurrent is detected.

Japanese Patent Laid-Open No. 10-14228

  Thus, by providing the overcurrent protection circuit, it is possible to prevent damage to the circuit components of the power supply circuit including the regulator. However, it is not sufficient to provide an overcurrent protection circuit in order to protect a load such as an LSI supplied with a voltage from a regulator. It is effective to separately provide a reset circuit for electrically disconnecting the regulator and the load such as the LSI.

  In particular, in the case of a load such as an LSI that requires a plurality of power supply voltages as described above, the following problems occur. If supply of either power supply voltage from the regulator stops due to a short circuit of the output voltage, (1) the operation becomes unstable due to an I / F error with the peripheral LSI or malfunction of the internal circuit of the LSI, and control by the LSI Cause equipment to run away. (2) There is a problem that the LSI itself is destroyed due to an abnormality in the power supply voltage of the LSI.

  Patent Document 1 has a problem that it does not specifically describe providing a reset circuit for electrically cutting off a power supply circuit and a load supplied with a voltage from the power supply circuit. In particular, when a plurality of voltages having different voltage values are supplied from the regulator to the load, there is a problem that a response when the supply of the voltage is stopped is not described. In addition, when the IC chip of the power supply circuit provided with the regulator and the reset circuit are provided separately, there is a problem that a space is required and the wiring length becomes long.

  The present invention has been made in view of such problems of the prior art, and an object of the present invention is to provide a power supply circuit in which a composite circuit including a reset circuit is integrated and mounted on an IC chip to reduce the number of components. It is to be.

  In the power supply circuit of the present invention that achieves the above object, a regulator, an overcurrent protection circuit attached to the regulator, a short circuit detection circuit for the output voltage of the regulator, and an output voltage of the regulator are supplied to the IC chip. A load reset circuit is mounted.

  In the power supply circuit of the present invention, the regulator is a linear regulator.

  In the power supply circuit of the present invention, the regulator is a switching regulator.

  The power supply circuit of the present invention is characterized in that a plurality of regulators having different output voltages are mounted on the IC chip.

  The power supply circuit according to the present invention is characterized in that the reset circuit outputs a reset signal when the input voltage of the power supply circuit is lower than a predetermined value.

  The power supply circuit according to the present invention is characterized in that the reset circuit outputs a reset signal in response to a signal from the short circuit detection circuit.

  The power supply circuit of the present invention is characterized in that the reset circuit outputs a reset signal when an input voltage of the power supply circuit is lower than a predetermined value and / or a signal of the short circuit detection circuit.

  In the power supply circuit of the present invention, a capacitor is connected to the IC chip, and a CR low-pass filter is configured by the capacitor and a resistor mounted on the IC chip.

  In the power supply circuit of the present invention, the CR low-pass filter is connected between the short-circuit detection circuit and the reset circuit.

  Further, in the power supply circuit of the present invention, the short circuit detection circuit has monitoring means for monitoring each output voltage of the plurality of regulators, and one of the monitoring means detects a short circuit of the output voltage of one of the regulators. A means is provided for stopping the operation of the other regulator when it is detected.

  In the power supply circuit of the present invention, since a plurality of circuits including a reset circuit are integrated and mounted on an IC chip, the number of components can be reduced. In addition, circuit components can be protected from damage due to impact or electrostatic breakdown.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 5 is a circuit diagram showing an example of a linear regulator applied to the power supply circuit of the present invention. In FIG. 5, reference numeral 71 denotes a linear regulator, and components are mounted on the IC chip 72. As these components, a voltage dividing resistor (Ra, Rb) 73, a reference voltage (Vref) generation circuit 74, a comparator (amplifier) 75, and a power transistor 76 are provided. The IC chip 72 is provided with pins Pr (Vout2), Ps (Vcc2), and Pt (GND). A ground line 80 is connected to the pin Pt.

  The linear regulator 71 adjusts the voltage value of the voltage input from the pin Ps and supplies the output voltage from the pin Pr to the load. When the input voltage fluctuates, a constant voltage is output under the control of the power transistor 76. For this reason, it is possible to perform voltage adjustment with high stability. Thus, the advantages of the linear regulator are as follows: (1) Since it operates by continuous and linear analog control, the accuracy of the output voltage is good and the stability is high. (2) There are few ripples and noises, and no malfunction occurs.

  1 and 2 are circuit diagrams showing a first embodiment of the present invention. The signal lines in FIGS. 1A, 1B, and 1C correspond to the signal lines in FIGS. 2A, 2B, and 2C, respectively. 1 and 2, the power supply circuit 50 includes an IC chip 2 in which a first linear regulator 1, a second linear regulator 11, a short circuit detection circuit 20, and a reset circuit 30 are provided. Further, a first overcurrent protection circuit 7 and a second overcurrent protection circuit 17 are connected to the first linear regulator 1 and the second linear regulator 11, respectively.

  The outer periphery of the IC chip 2 is provided with a terminal Pa to which the input power supply voltage Vin is input, a terminal Pb to which an active low reset signal is output, and a terminal Pc to which an external capacitor Cd is connected. The external capacitor Cd forms a CR low-pass filter with a time constant Td together with the resistor R3. The operation of this CR low-pass filter will be described later. Further, a terminal Pd connected to ground (GND), a terminal Pe from which the output voltage Vout1 of the first linear regulator 1 is output, and an output voltage Vout2 of the second linear regulator 11 are output to the outer periphery of the IC chip 2. A terminal Pf is provided. Note that capacitors C1, C2, and C3 for noise removal are connected to the signal line of the input power supply voltage Vin and the signal lines of the output voltages of the first linear regulator 1 and the second linear regulator 11, respectively.

  The first linear regulator 1 is provided with a voltage dividing resistor (R5, R6) 3, a reference voltage (Vref) generation circuit 4, a comparator (amplifier) 5, and a power transistor (Q4) 6. The input power supply voltage Vin is input to the collector of the power transistor 6. The emitter of the power transistor (Q4) 6 is connected to the terminal Pe from which the output voltage Vout1 of the first linear regulator 1 is output.

  The second linear regulator 11 is provided with a voltage dividing resistor (R8, R9) 13, a comparator (amplifier) 15, and a power transistor (Q6) 16. The input power supply voltage Vin is input to the collector of the power transistor (Q6) 16. The emitter of the power transistor (Q6) 16 is connected to a terminal Pf from which the output voltage Vout2 of the second linear regulator 11 is output. The reference voltage (Vref) generation circuit 4 is shared with the first linear regulator 1. The operations of the first linear regulator 1 and the second linear regulator 11 are basically the same as those described with reference to FIG.

  A first overcurrent protection circuit 7 is connected to the first linear regulator 1. The first overcurrent protection circuit 7 includes a resistor (R4) 9 and a transistor (Q5) 8. The resistor (R4) 9 is connected between the emitter of the power transistor (Q4) 6 and the terminal Pe. The transistor (Q5) 8 has a base connected to the emitter of the power transistor 6, a collector connected to the base of the power transistor 6, and an emitter connected to the terminal Pe.

  Next, the operation of the first overcurrent protection circuit 7 will be described. The first overcurrent protection circuit 7 is a circuit that limits the output current of the first linear regulator 1 in order to protect the power transistor (Q4) 6 from an overcurrent such as a short circuit current or an overload current. . As described above, when the output current of the first linear regulator 1 increases due to a short circuit or overload of the output voltage supply line, the voltage drop across the resistor (R4) 9 increases. For this reason, the base-emitter voltage of the transistor (Q5) 8 increases, and the transistor (Q5) 8 is turned on. Therefore, the base current of the power transistor (Q4) 6 is drawn into the collector of the transistor (Q5) 8, and the output current of the power transistor (Q4) 6 is limited.

  The first overcurrent protection circuit 7 is mounted on the same IC chip 2 as the first linear regulator 1. For this reason, a space can be saved. Further, since it is mounted in the IC chip 2, the influence of noise and disturbance is reduced as compared with the case where it is provided outside the IC chip 2, and the reliability of the first overcurrent protection circuit 7 is improved. Further, the first overcurrent protection circuit 7 includes a resistor (R4) 9 and a transistor (Q5) 8, and can be manufactured in the same manufacturing process as the first linear regulator 1, thereby reducing the manufacturing cost. be able to.

  The second overcurrent protection circuit 17 is connected to the second linear regulator 11. The second overcurrent protection circuit 17 includes a resistor (R7) 19 and a transistor (Q7) 18. The connection relationship between the resistor (R7) 19 and the transistor (Q7) 18 of the second overcurrent protection circuit 17 and the circuit of the second linear regulator 11 is the same as the example of the first overcurrent protection circuit 7. . In addition, the effect of mounting on the same IC chip 2 as the second linear regulator 11 is the same as that of the example of the first overcurrent protection circuit 7.

  Next, the reset circuit 30 will be described. The reset circuit 30 includes a first reset signal forming unit during normal operation and a second reset signal forming unit during detection of a short circuit of the output voltage. The first reset signal forming unit includes a voltage dividing resistor (R1, R2) 31, a comparator (amplifier) 32, and a transistor (Q2) 33. The power supply of the reference voltage Vth1 is connected to the non-inverting input terminal (+) of the comparator 32. The second reset signal forming unit includes a comparator (amplifier) 35 and a transistor (Q1) 36. The comparator 36 has a Schmitt trigger circuit configuration, and a non-inverting input terminal (+) is connected to a power source of the reference voltage Vth2.

  When a voltage lower than the operation limit value of the linear regulator is input to the linear regulator, the output voltage of the linear regulator becomes unstable, and a peripheral circuit such as a CPU connected to the linear regulator malfunctions. Therefore, when the power supply of the linear regulator is turned on, it must be kept in a reset state until the input power supply voltage rises normally and the peripheral circuit is stabilized.

  Further, when the power supply of the linear regulator is turned off, it is necessary to instantaneously return the CPU and peripheral logic circuit to which the output voltage is supplied from the linear regulator to the initial state. The first reset signal forming unit of the reset circuit 30 is provided in order to realize these operations. As described above, the first reset signal forming unit of the reset circuit reliably starts up the peripheral logic circuit from the initial state when the power of the linear regulator is turned on / off, or at the time of an instantaneous power failure. Work to return to.

The first reset signal forming unit monitors the input power supply voltage Vin by the comparator 32, and when the input power supply voltage is lower than the detection voltage, sets the reset signal RESET to a low level. The detection voltage of the comparator 32 is set by the reference voltage Vth1 and the voltage dividing resistors R1 and R2. That is, the detection voltage (Vd) = Vth1 * (R1 + R2) / R2
It is.

  When the input power supply voltage Vin is lower than the detection voltage (Vd) of the comparator 32, the transistor 33 is turned on. Therefore, the inverting input terminal (−) of the comparator 35 is at a low level, and the input voltage is lower than the reference voltage Vth2, so that the transistor 36 operates. Therefore, the RESET signal output from the terminal Pb becomes a low level, and the load supplied with the output voltage of the linear regulator is reset. When the input power supply voltage Vin increases and becomes higher than the detection voltage (Vd), the RESET signal output from the terminal Pb becomes high level, and the load becomes operable.

  If the output voltage of the linear regulator is short-circuited during normal operation of the linear regulator due to destruction of peripheral parts (impact, electrostatic breakdown, etc.) or incorrect contact, the linear regulator itself is destroyed by the overcurrent protection circuit. It can be prevented. However, peripheral LSIs that operate using the output voltage from the linear regulator as a power source become unstable. In particular, an LSI such as a CPU or a DSP that requires a plurality of power supplies as described above may cause a runaway due to a malfunction, and in the worst case, the device may be destroyed.

  In order to prevent the occurrence of such a situation, when a short circuit occurs in the output voltage supply line of the linear regulator, it is necessary to immediately stop the operation of the peripheral LSI by setting the reset signal to a low level. Further, when the short circuit state or the overcurrent is resolved, it is necessary to bring up the circuit from the initial state and restore the normal operation.

  The second reset signal forming unit composed of the comparator (amplifier) 35 and the transistor (Q1) 36 is provided for protecting equipment such as a peripheral LSI to which an output voltage is supplied from such a linear regulator. It is. The second reset signal forming unit is controlled by a signal from the short circuit detection circuit 20.

  Next, the operation of the short circuit detection circuit 20 will be described. The short circuit detection circuit 20 includes a comparator 21, a transistor (Q 3) 22, and a resistor (R 3) 23. The power supply of the reference voltage Vth3 is connected to the non-inverting input terminal (+) of the comparator 21. The reference voltage Vth3 is set to 1 V, for example. Further, two inverting input terminals (−) of the comparator 21 are provided, one of which is connected to a lead wire that supplies the output voltage of the first linear regulator 1. The other inverting input terminal of the comparator 21 is connected to a lead wire that supplies the output voltage of the second linear regulator 11.

  The comparator 21 monitors the voltage values of the output voltages Vout1 and Vout2 of the first linear regulator 1 and the linear regulator 11. That is, the comparator 21 compares the reference voltage (Vth3 = 1V) with the voltage values of the output voltages Vout1 and Vout2. When one of the output voltages Vout1 and Vout2 is short-circuited to GND, the voltage values of the output voltages Vout1 and Vout2 become 1 V or less, and the transistor 22 (Q3) is turned on by the output signal of the comparator 21.

  When the transistor (Q3) 22 is turned on, the input of the inverting input terminal (−) of the comparator 35 goes to the low level through the resistor (R3) 23. For this reason, the transistor 35 is turned on by the output signal of the comparator 35. Therefore, an active-low reset signal is output from the terminal Pb of the IC chip 2 to reset the load.

  As described above, the reset circuit 30 and the short circuit detection circuit 20 are mounted on the same IC chip 2 as the first linear regulator 1 and the second linear regulator 11. For this reason, a space can be saved. Moreover, since it is mounted in the IC chip 2, the influence of noise and disturbance is less than that provided outside the IC chip 2, and the reliability of the short circuit detection circuit 20 and the reset circuit 30 is improved.

  Furthermore, the short circuit detection circuit 20 and the reset circuit 30 are configured by resistors, transistors, and comparators, and can be manufactured in the same manufacturing process as the first linear regulator 1 and the second linear regulator 11, thereby reducing manufacturing costs. can do. It should be noted that by mounting the reset circuit 30 and the short circuit detection circuit 20 on the IC chip 2, the signal lines connecting the first linear regulator 1, the second linear regulator 11, the short circuit detection circuit 20, and the reset circuit 30 are reduced. The wiring length can be shortened.

  In the example of FIG. 1, the reset circuit 30 is provided with a first reset signal forming unit during normal operation and a second reset signal forming unit when detecting a short circuit of the output voltage. However, in the present invention, only the first reset signal forming unit or the second reset signal forming unit may be provided. The configuration of the reset circuit can be appropriately set according to the use of the power supply circuit.

  In FIG. 1, the resistor (R3) 23 forms a CR low-pass filter as described above together with the external capacitor (Cd). The CR low-pass filter functions as a signal delay circuit and noise elimination circuit, and operates so that the reset signal does not go low due to the rush current or noise that occurs at power-on or when the standby mode is switched to the normal mode. .

  FIG. 6 is a circuit diagram showing a connection example of the CR low-pass filter in FIG. The same parts as those in FIG. 1 are denoted by the same reference numerals. A CR low-pass filter including a resistor (R3) 23 and a capacitor Cd is connected between the short-circuit detection circuit 20 and the subsequent stage of the reset circuit 30, that is, the second reset signal forming unit.

  FIG. 7 is a characteristic diagram showing operating characteristics of the CR low-pass filter. The characteristics of (a), (b), and (c) in FIG. 7 correspond to the characteristics of points (a), (b), and (c) in FIG. 6, respectively. When the short circuit detection circuit 20 detects the short circuit of the output voltage supply line or the occurrence of overcurrent, the output signal of the short circuit detection circuit 20 changes from the H level to the L level.

In this way, when the point signal (a) becomes L level, the charge stored in the capacitor (Cd) is gradually discharged through the resistor (R3). Therefore, at the point (b) of the output point of the CR low-pass filter, A voltage waveform that decreases at a predetermined delay time t1 is formed. Here, the delay time t of the CR low-pass filter is
t = C × R
It is represented by If R3 = 1 KΩ and Cd = 0.1 μF, the delay time t1 is
t1 = {(0.1 × 10 ⁻⁶ ) / C} × {(1 × 10 ³ ) / R} = 100 μsec
It becomes.

The output of the CR low-pass filter is compared with the reference voltage (Vth2) by the comparator 35 at the rear stage of the reset circuit. Then, the signal changes from the H level to the L level with a delay of time t2 from the occurrence of the short circuit, and a reset signal such as point (c) is output. If the reference voltage (Vth2) of the comparator 35 is set to the intermediate voltage (50%) of the signal at point (b), the delay time t2 of the reset signal is
t2 = 100μsec × 0.5 = 50μsec
It becomes.

  FIG. 8 is a characteristic diagram showing another operation of the CR low-pass filter. The signal delay circuit using the CR low-pass filter is a rush current that occurs at the moment when the output current suddenly increases when shifting from the standby mode to the normal mode. It works so as not to become low level. Hereinafter, such an operation of the CR low-pass filter will be described.

  In FIG. 8, the characteristics of (a), (b), and (c) correspond to the characteristics of points (a), (b), and (c) in FIG. 6, respectively. Here, it is assumed that the output voltage of the linear regulator instantaneously drops due to the rush current. In this case, the signal at point (a) changes from the H level to the L level at the timing when the output voltage of the linear regulator drops below the threshold voltage Vth3. The output voltage of the linear regulator is then restored to a steady state. When the voltage recovers to the steady state, when the voltage becomes higher than the threshold voltage Vth3, the signal at point (a) changes from the L level to the H level.

  The signal at point (b), which is the output point of the CR low-pass filter, decreases with the delay time t1 as described above. However, at the timing when the signal at the point (a) changes from the L level to the H level, the signal at the point (b) turns from decreasing to increasing and recovers to the H level. The timing at which the signal at point (b) changes from decreasing to increasing is at a voltage higher than the threshold voltage Vth2.

  For this reason, the reset signal output at point (c) maintains the H level and does not change to the L level. In other words, since the load is not reset by an instantaneous change in the output voltage of the linear regulator, the operation of the load such as an LSI can be stabilized.

The CR low-pass filter has a function of removing signal noise from the reset signal, and removes signals such as noise having a cutoff frequency (fc) or higher. The cutoff frequency fc at this time is
fc = {1 / (2πCR)} (Hz)
Is required.

  In an LSI that requires a plurality of power supplies, if the core voltage of the IC becomes higher than the I / O voltage, the inside of the LSI may be destroyed and may fail. For example, when the I / O voltage (3.3 V) is short-circuited to 0 V, the core voltage becomes higher in potential when the core voltage (2.5 V) is supplied as it is.

  FIG. 3 and FIG. 4 are power supply circuits showing another embodiment of the present invention made to cope with such a situation. 3 and 4 are circuits having a function of stopping the output of the linear regulator in addition to setting the reset signal to a low level when the output supply line of the linear regulator is short-circuited. The same portions as those in FIGS. 1 and 2 are denoted by the same reference numerals, and only the portions different from FIGS. 1 and 2 will be described.

  In the power supply circuit 80 in FIG. 3, the short circuit detection circuit 70 includes a comparator 71 that monitors the output voltage Vout1 of the first linear regulator 1 and a comparator 72 that monitors the output voltage Vout2 of the second linear regulator 11. A transistor (Q3) 73 and a resistor (R4) 75 are connected to the comparator 71. The comparator 72 is connected to a transistor (Q4) 74 and a resistor (R5) 76.

  The collector of the transistor (Q3) 73 and the collector of the transistor (Q4) 74 are connected to the input terminal of the AND circuit 77. The collector of the transistor (Q3) 73 is connected to the on / off control unit 41 provided in the first linear regulator 1, and the collector of the transistor (Q4) 74 is connected to the on / off control unit 42 provided in the second linear regulator 11. Connected to.

  3 and 4, when a short circuit occurs in the output voltage Vout1 of the first linear regulator 1, the input voltage at the inverting input terminal of the comparator 71 is lower than the reference voltage Vth3. Thus, the transistor 73 is turned on. At this time, when the output voltage Vout2 of the second linear regulator 11 is normal, the output level of the AND circuit 77 is L level.

  Similarly, when the output voltage Vout2 of the second linear regulator 11 is short-circuited and the output voltage Vout1 of the first linear regulator 1 is normal, the output level of the AND circuit 77 is L level. When the output level of the AND circuit 77 is L level, the reset signal of the reset circuit 30 becomes low level, and the load of the linear regulator is reset.

  In addition, when the output voltage Vout1 of the first linear regulator 1 is short-circuited and the output voltage Vout2 of the second linear regulator 11 is normal, the transistor 73 is turned on as described above. For this reason, the on / off controller 42 is turned off, the second linear regulator 11 is turned off, and the output of Vout2 is stopped.

  Similarly, when the output voltage Vout2 of the second linear regulator 11 is short-circuited and the output voltage Vout1 of the first linear regulator 1 is normal, the transistor 74 is turned on as described above. For this reason, the on / off controller 41 is turned off, the first linear regulator 1 is turned off, and the output of Vout1 is stopped.

  As described above, the operation principle of the circuit shown in FIGS. 3 and 4 is the same as that of FIGS. However, in the circuits of FIGS. 3 and 4, the output voltages Vout1 and Vout2 of the first linear regulator 1 and the second linear regulator 11 are monitored by the individual comparators 71 and 72, respectively. The output sides of the transistors (Q3) 73 and (Q4) 74 connected to the output sides of the comparators 71 and 72 are connected to an AND circuit. Therefore, when a short circuit occurs in one or both of the output voltages Vout1 and Vout2, the reset signal is set to a low level.

  In the embodiment of the present invention, a power supply circuit is configured by mounting a plurality of linear regulators and composite parts such as an overcurrent protection circuit, a short circuit detection circuit, and a reset circuit on the IC chip 2. In this way, by reducing the size of the power supply circuit and reducing the cost, it is possible to realize the packaging by integrating the composite parts formed by the IC.

  When these composite parts are added as an external circuit, the protection circuit does not function when the parts (IC / transistor resistance, etc.) of this circuit part are damaged by impact or electrostatic breakdown. Damage caused by impact or electrostatic breakdown occurs at the same probability in both the circuit connected to the regulator output and the protection circuit, so the risk can be reduced by reducing the number of parts by combining them.

  The embodiment of the present invention has been described above. The present invention is not limited to these examples, and various modifications are possible. For example, the regulator can be configured to use a switching regulator in addition to the linear regulator. Further, the present invention can also be applied when a single regulator is used.

  9 and 10 are circuit diagrams showing the configuration of the switching regulator when a switching regulator is used as the regulator mounted on the IC chip 2. In FIG. 9, the switching regulator 51 is constituted by each component mounted on the IC chip 52. A diode 53 (D) is connected between the input terminal Vin and the output terminal Vout of the IC chip 52. 54 is a power transistor, 55 is a pre-driver, 56 is a comparator, 57 is an oscillator (OSC), and 58 is PWM control. Also, 59 is an internal resistor (R1, R2) for adjusting the output voltage, 60 is a reference voltage generating circuit, 61 is an amplifier, and 63 is an input circuit comprising a capacitor Ca and a coil L.

  Next, the operation of the circuit of FIG. 9 will be described. FIG. 9 shows an example of a step-up switching regulator. The on / off control of the npn type power transistor 54 is performed by a reference voltage (Vref) generation circuit 60, internal resistors 59 (R1, R2), an amplifier 61, a comparator 56, an oscillator 57, a PWM control 58, and a pre-driver 55. The voltage fed back from the terminal Voutl is compared by the amplifier 61 using the reference voltage (Vref) and the internal resistors 59 (R1, R2) for adjusting the output voltage. At this time, the value of the output voltage is determined by changing the ratio of the internal resistance for adjusting the output voltage. The output of the amplifier 61 is phase compensated by a capacitor Cd (Ccomp). The output of the phase compensated amplifier 61 is input to the inverting input terminal of the comparator 56. The output signal of the oscillator 57 is input to the non-inverting input terminal of the comparator 56.

  The comparator 56 compares the signal from the amplifier 61 with the waveform from the oscillator 57. Simultaneously, the PWM control 58 sends the output of the comparator 56 to the pre-driver 55 as a switching duty width signal. The output of the pre-driver 55 turns on / off the power transistor 54 connected to the pre-driver 55 in synchronization with the frequency of the oscillator 57. By continuously performing these operations, the output voltage is stabilized.

  When the power transistor 54 is turned on, a current flows through a path indicated by a broken line ◯ 1 (a circled number is displayed in this way for conversion reasons. The same applies hereinafter), and energy is stored in the coil L of the input circuit 63. Next, when the power transistor 54 is turned off, the coil L releases the stored energy in an attempt to continue the current flow. The electrical energy accumulated in the coil L is released to the output voltage terminal (Voutl) as shown by the path of the alternate long and short dash line 2 when the power transistor 54 is turned off to increase the output voltage supplied to the load. Let

  As described above, when the power transistor 54 is turned off, the accumulated energy of the coil L flows into the capacitor Cb through the diode 53 and the output terminal Voutl through the path ○ 2. When the power transistor is turned on again, energy is stored in the coil L. On the output side, a current flows through a path ◯ 3 by energy stored in the capacitor Cb. The energy stored in the capacitor Cb does not flow into the power transistor 54 due to the diode 53 (D), but is output only to the output side.

  FIG. 10 is a circuit diagram showing the step-down switching regulator 51a. In this example, as compared with the step-up switching regulator example of FIG. 6, the power transistor 54a uses a pnp type transistor instead of the npn type transistor. The diode 53 is connected between the ground and the output voltage terminal (Voutl). In addition, only the capacitor | condenser Ca is used for the input circuit 63, and the coil L and the capacitor | condenser Cb are connected to the output circuit. Resistors Rx and Ry are connected between the power transistor 54a and the pre-driver 55. Since other configurations are the same as those in FIG. 6, a detailed description thereof will be omitted.

  The input voltage (Vin) is transmitted to the output circuit by the switching operation of the power transistor 54a provided in the step-down switching regulator 51a. When the power transistor 54a is turned on, a current flows through a path indicated by a broken line ◯ 1, and power is supplied to the capacitor Cb and the output side through the coil L. At this time, electric energy is stored in the coil L and the capacitor Cb. Next, when the power transistor 54a is turned off, the coil L tries to keep the current flowing (Lenz's law) and releases the stored energy to the output side through the path of the alternate long and short dash line 2. At this time, if the diode 53 is not connected, a current path is not formed, so that the electrical energy stored in the coil (L) cannot flow.

  At the same time, the electric energy stored in the capacitor Cb is also released to the output side through the two-dot chain line ◯ 3. When the power transistor 54a is turned on again, power is supplied to the output side through the coil L. At this time, a part of the electric energy is stored in the coil L and the capacitor Cb. In this way, the coil L functions to store an input voltage when the power transistor 54a is on, and to release the electric energy stored when the power transistor 54a is off, and to output a constant power.

  Similarly to the coil L, the capacitor Cb serves to level the power supply to the output side. The step-down switching regulator operates to take in only the power necessary for the output from the input by the switching operation. Therefore, the loss of the regulator can be reduced compared to the linear regulator.

  A switching regulator controls output voltage by switching electric power at a high frequency (several tens of k to several MHz). This switching regulator always operates in either on or off mode of transistor operation. The switching regulator is a system that stabilizes the DC output voltage by changing the ratio of the on and off times.

  The advantages of the switching regulator are: (1) The power loss of the control transistor is small and the power conversion efficiency is good. (2) Since the power loss is small, the temperature rise is small, and a small IC package can be manufactured. (3) In voltage adjustment, not only step-down but also step-up and positive / negative inversion are possible.

  As described above, according to the present invention, since a plurality of circuits including a reset circuit are integrated and mounted on the IC chip, the number of components of the power supply circuit can be reduced. In addition, circuit components can be protected from damage due to impact or electrostatic breakdown.

It is a circuit diagram showing an embodiment of the present invention. It is a circuit diagram showing an embodiment of the present invention. It is a circuit diagram which shows other embodiment of this invention. It is a circuit diagram which shows other embodiment of this invention. It is a circuit diagram which shows the example of a linear regulator. It is a circuit diagram which shows the example of CR low pass filter. It is a characteristic view which shows the characteristic of CR low pass filter. It is a characteristic view which shows the characteristic of CR low pass filter. It is a circuit diagram showing an embodiment of the present invention. It is a circuit diagram showing an embodiment of the present invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... 1st linear regulator, 2 ... IC chip, 3, 13 ... Voltage dividing resistor, 4 ... Power supply of reference voltage, 5, 15 ... Comparator, 6, 16 ... Power transistor, 7, 17 ... Overcurrent protection circuit, 8 ... Transistor, 9 ... Resistance, 11 ... Second linear regulator, 20 ... Overcurrent protection circuit, 30 ... Reset Circuit, 41, 42 ... ON / OFF control unit, 50, 80 ... Power supply circuit, 71, 72 ... Comparator, 77 ... AND circuit

Claims (10)

The IC chip includes a regulator, an overcurrent protection circuit attached to the regulator, a short circuit detection circuit for the output voltage of the regulator, and a load reset circuit to which the output voltage of the regulator is supplied. A power circuit. The power supply circuit according to claim 1, wherein the regulator is a linear regulator. The power supply circuit according to claim 1, wherein the regulator is a switching regulator. 4. The power supply circuit according to claim 1, wherein a plurality of regulators having different output voltages are mounted on the IC chip. 5. The power supply circuit according to claim 1, wherein the reset circuit outputs a reset signal when an input voltage of the power supply circuit is lower than a predetermined value. 6. 5. The power supply circuit according to claim 1, wherein the reset circuit outputs a reset signal in response to a signal from the short-circuit detection circuit. 5. The reset circuit according to claim 1, wherein the reset circuit outputs a reset signal when an input voltage of the power supply circuit is lower than a predetermined value and / or a signal of the short circuit detection circuit. The power supply circuit described. 8. The power circuit according to claim 1, wherein a capacitor is connected to the IC chip, and a CR low-pass filter is configured by the capacitor and a resistor mounted on the IC chip. The power supply circuit according to claim 8, wherein the CR low-pass filter is connected between the short-circuit detection circuit and the reset circuit. The short circuit detection circuit has monitoring means for monitoring the output voltage of each of the plurality of regulators, and when one of the monitoring means detects a short circuit of the output voltage of one of the regulators, 10. The power supply circuit according to claim 4, further comprising means for stopping the operation of the regulator.

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