This application is based on and incorporates herein by reference Japanese patent applications No. 2010-3878 filed on Jan. 12, 2010 and No. 2010-139306 filed on Jun. 18, 2010.
The present invention relates to a signal output circuit, which outputs a drive control signal to a switching element connected in series with an electric load between a power source and a ground.
An interior light, a rear light, a flasher light or the like is recently controlled to produce gradually changing brightness of light to provide fanciness as electric equipment of a vehicle or produce light of fixed brightness irrespective of changes in a power supply voltage of a battery. The brightness of a light source such as a light bulb and a light-emitting diode is controlled by driving a switching element such as a MOSFET by pulse-width modulation (PWM) control. Since the number of electric loads such as lights to be driven increases recently, radio noises, which are generated at time of driving the electric loads, increase correspondingly.
As technology for reducing radio noises generated when a PWM control is performed, as disclosed in the following patent documents 1 and 2, it is proposed to shape a waveform of a PWM signal into a trapezoid form so that a current supplied to a load changes slowly or gradually thereby suppressing noises. According to this technology, a voltage applied to a gate of a switching element such as a MOSFET changes at low levels during a period, in which a current waveform changes at a uniform rate. Since the switching element continues to have a high on-resistance during such a period, the switching element generates heat. The amount of heat thus generated increases, as the amount of a drive current increases or the number of electric loads to be driven increases. As a result, it becomes difficult to promote heat radiation. Since reduction in radio noise and suppression of heat generation are in a relation of trade-off, the radio noise reduction and the heat generation suppression need be appropriately adjusted.
Patent document 1: JP 3685108 (US 2002/0171455 A1)
Patent document 2: JP 2009-16697A
Patent document 3: JP 2007-13916A (US 2006/0267665 A1)
In patent document 1, for example, trade-off between radio noise reduction and heat generation suppression is considered. As a result, a very complicated circuit configuration is needed. In patent document 3, a waveform of a PWM signal is modified to a pseudo-sinusoidal waveform, which is more effective to reduce noise generation and suppress heat generation.
Specifically, in patent document 3, the pseudo-sinusoidal waveform is generated by sequentially switching connections of a plurality of constant current sources while monitoring a source voltage of a FET. According to this feedback control, circuit configuration need be complicated and the circuit becomes more susceptible to noises generated by other devices. If the signal waveform is smoothed by simply using a CR filter, rise of the signal waveform is smoothed but fall of the same is not smoothed.
It is therefore an object of the present invention to provide a signal output circuit, which controls a switching element by a gradually changing waveform like a sinusoidal waveform in a simple configuration.
According to the present invention, a signal output circuit is provided for outputting a drive signal to a voltage-controlled switching element, which is connected in series with a load between a power source and a ground, in accordance with a control signal inputted thereto. The signal output circuit comprises a current generation circuit, a current mirror circuit and a control part. The current generation circuit generates a current based on a relation between a potential at a control terminal of the switching element and either one of a voltage of a controlled power source and a ground potential. The current mirror circuit supplies, as a mirror current, a current generated by the current generation circuit. The control part controls an operation of the current mirror circuit in accordance with a level change of the control signal. The control part operates the current mirror circuit to supply a discharge current from the control terminal and stops an operation of the current mirror circuit to supply a charge current to the control terminal.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
FIGS: 12A and 12B are a waveform diagram and a table of control signals applied in the fifth embodiment, respectively;
(First Embodiment)
Referring to
A second current mirror circuit 7, which is a control current mirror circuit, is provided at a ground side. One current path of the current mirror circuit 5 is connected to the current mirror circuit 7 through a switch circuit 8, which is provided as on/off control part. The other current path of the current mirror circuit 5, that is, the current source 6 side, is also connected to the current mirror circuit 7.
A common junction between the current source 6 and the current mirror circuit 7 is connected to a gate (control terminal) of the MOSFET 1. A capacitor 9 is connected between the gate and a source of the MOSFET 1. The capacitor 9 is set to have a capacitance, which is greater than a capacitance component between a gate-source capacitance of the MOSFET 1.
The signal output circuit 3 in
An N-channel MOSFET 8T, which corresponds to the switch circuit 8 in
As shown in
When the MOSFET 8T is turned on, the current mirror circuit 7 stops its operation. At this time, the current supplied from the current mirror circuit 5 through the current source 6 flows to the gate of the MOSFET 1. The MOSFET 1 has a capacitance component between its gate and its source. The capacitor 9 is connected in parallel to the capacitance component of the MOSFET 1. The current flowing to the gate charges the capacitor 9 and the capacitance component of the MOSFET 1 and raises a gate potential Vg to a higher level. The MOSFET 1 is thus turned on to supply a current to the light 2.
In this operation, when the PWM signal changes its level from the low level to the high level as indicated by (a) in
Vg=Vcp[1−exp{−t/(CR)}] (1)
Since the MOSFET 1 is configured in the source follower, a potential Vs of the source, which is common to the light 2, rises gradually as indicated by a waveform (c) in
When the PWM signal charges its level from the high level to the low level as indicated by (a), the transistors 7b and 5b are turned on. The gate-source capacitance of the MOSFET 1, which is in the charged state, is thus discharged at the CR time constant. The current mirror circuit 7 allows a current, which discharges electricity stored in the capacitor 9 and the like, as well as the current supplied from the current mirror circuit 5 to flow therethrough. The gate potential Vg and the source potential Vs also fall gradually or smoothly as indicated by (b) and (c), respectively. The current Il supplied to the light 2 also falls gradually as indicated by (d) similarly to the source potential Vs. The waveform of the current Il supplied to the light 2 is generally symmetrical between a rise time and a fall time. The current waveforms are thus generally turn-backs between the rise time and the fall time with respect to time.
According to the first embodiment, the MOSFET 8 controls the operation of the current mirror circuit 7 in accordance with the level change of the PWM signal applied to its gate so that the mirror current flows through the current source 6 by the operation of the current mirror circuit 7. This current flows to the gate of the MOSFET 1 thereby to discharge the electricity charged in the capacitance between the gate and the source of the MOSFET 1. When the operation of the current mirror circuit 7 is stopped, the current flowing from the current mirror circuit 5 through the current source 6 is supplied to the gate of the MOSFET 1 as the charging current.
The gate potential of the MOSFET 1 gradually changes in accordance with the time constant of the capacitance and an internal resistance component (resistance of the resistor 6R), which the current source 6 has. In addition, the charge current and the discharge current are constant current-controlled by the combination of the current source 6 and the current mirror circuits 5, 7, so that the changes in the voltage waveform at the charge time and the discharge time generally become turn-back shape with respect to time. As a result, the current I1 supplied to the light 2 is changed gradually to reduce radio noise in any case when the MOSFET 1 is turned on and off. The above operation is controlled by an open-loop control and is less susceptible to noises. As a result, the operation is controlled stably.
The capacitor 9 is connected between the gate and the source of the MOSFET 1, and the capacitance of the capacitor 9 is set to be larger than the capacitance component of the MOSFET 1. As a result, the rate of change of the gate potential waveform, the source voltage waveform and the current waveform shown in
The MOSFET 1 is driven at the high potential side, that is, operated as the source follower so that the source potential changes following changes in the gate potential. As a result, the current flowing to the light 2 also changes gradually and the radio noise is effectively reduced. The controlled power source voltage Vcp is supplied by boosting the power source voltage VB by the booster circuit 4 so that the MOSFET 1, which is driven according to the high side driving method, is driven to be fully turned on.
The current source 6 is formed in the current supply path of the controlled power source voltage Vcp and includes the resistor 6R, one end of which is connected to the gate of the MOSFET 1. As a result, the charge and discharge time constants are determined by the resistance of the resistor element 6R.
The operation of the current mirror circuit 7 connected in series with the current mirror circuit 5 is controlled in accordance with the level change of the PWM signal by the MOSFET 8T connected in parallel to the NPN transistor 7b. Thus, when the current mirror circuit 7 operates, the discharge current is supplied from the gate of the MOSFET 1. When the current mirror circuit 7 is stopped, the charge current is supplied to the gate of the MOSFET 1 by the current, which flows from the current mirror circuit 5 through the current source 6.
(Second Embodiment)
A second embodiment is shown in
A signal output circuit 11 according to the second embodiment has transistors for correcting a current gain in addition to the current mirror circuits 5 and 7, which are provided at the power source side and the ground side, respectively. An emitter of a PNP transistor 13 is connected to the bases of the PNP transistors 5a and 5b through a resistor 12. A base and a collector of the PNP transistor 13 are connected to the collector of the PNP transistor 5a and the ground, respectively.
An emitter and a collector of a PNP transistor 14 are connected between the collector of the PNP transistor 5b and the collector of the NPN transistor 7a. The base of the PNP transistor 14 is connected to the collector of the PNP transistor 5a together with the base of the PNP transistor 14. The PNP transistor 14 is provided to avoid influence of the early effect by equalizing the emitter-collector voltages of the PNP transistors 5a and 5b to each other. An emitter of a NPN transistor 15 is connected to the bases of the NPN transistors 7a and 7b. A collector and a base of the NPN transistor 15 are connected to the power source through a resistor 16 and the collector of the NPN transistor 7a. A NPN transistor 17 and diodes 18 to 18c are provided to avoid influence of the early effect similarly as the transistor 14.
A collector and an emitter of a NPN transistor 17 are connected between the gate of the MOSFET 1 and the collector of the NPN transistor 7b. The three diodes 18a to 18c connected in series are connected between the power source and the ground through a current source 19. A base of the transistor 17 is connected to an anode of the diode 18a. A collector-emitter voltages of the NPN transistors 7a and 7b are both set to 2×Vbe.
According to the second embodiment, a rate of waveform change of a charge/discharge current relative to the gate of the MOSFET 1 is controlled with high accuracy by increasing an accuracy of a ratio of mirror operation of the current mirror circuits 5 and 7.
The current mirror circuits may be configured in a plurality of variations. For example, the current mirror circuits may be configured with emitter resistors, in cascade connection and in Wilson type as shown in
(Third Embodiment)
A third embodiment is shown in
A signal output circuit 21 according to the third embodiment is provided with a rapid charge circuit (charge assist circuit) 22C and a rapid discharge circuit (discharge assist circuit) 22D in addition to the signal output circuit 3 of the first embodiment. Further, comparators 23, 24, and a logic circuit 25 are provided for controlling the rapid charge circuit 22C and the rapid discharge circuit 22D. The circuit 22C and the rapid discharge circuit 22D are connected between the booster circuit 4 of the controlled power source voltage Vcp and the ground. A common junction of the rapid charge circuit 22C and the rapid discharge circuit 22D is connected to the gate of the MOSFET 1.
The comparators 23 and 24 are provided to control the logic circuit 25. The comparator 23 compares a predetermined threshold value Vth applied to its non-inverting input terminal and a gate potential of the MOSFET 1 applied to its inverting input terminal. The comparator 23 thus produces a comparison result signal to the logic circuit 25. The comparator 24 compares the power source voltage VB applied to its non-inverting input terminal and a potential applied to its inverting input terminal. This potential is lower than the gate potential of the MOSFET 1 by a reference voltage Vref. The comparator 24 thus produces a comparison result signal to the logic circuit 25.
The rapid charge circuit 22C and the rapid discharge circuit 22D are configured as shown in
The rapid charge circuit 22C forms a bypass path, which passes a charge current to rapidly increase the gate potential after the MOSFET 1 has been fully turned on, in case that the gate of the MOSFET 1 is charged through the current source 6. The rapid discharge circuit 22D also forms a bypass path, which passes a discharge current to rapidly decrease the gate potential of the MOSFET 1 from the highest level to a level, at which the MOSFET 1 starts to be turned off, in case that the current mirror circuit 7 operates to discharge the capacitor 9 from the gate of the MOSFET 1 through the current source 6. The PWM signal is applied to the logic circuit 25 so that the logic circuit 25 operates to turn on and off the switch circuit 8. Further details of the configuration and operation will be described below with reference to the fifth embodiment.
A principal operation of the third embodiment will be described with reference to
When the PWM signal changes its level from the high level to the low level, the logic circuit 25 changes a control signal IN2 from a low level to a high level. The MOSFET 32 is thus turned on, and the bypass path is formed to pass the discharge current from the gate of the MOSFET 1 to lower the gate potential Vg rapidly. When the gate potential falls to be lower than the voltage (VB+Vref), the control signal IN2 is changed to the low level. Since the rapid charge/discharge circuit 22 operates as described above, a time interval for actually turning on the MOSFET 1 is made closer to a time interval of a high level pulse width of the PWM signal even when the rise and fall of the gate potential of the MOSFET 1 is gradually changed.
According to the third embodiment, the rapid charge/discharge circuit 22 forms the bypass path to increase the charge/discharge current relative to the gate of the MOSFET 1 in a part of the operation period and a part of the operation stop period of the current mirror circuit 7. A charge/discharge interval in a time interval, in which radio noise is not suppressed because the MOSFET 1 is thus driven to the full on-state, is shortened. As a result, the on-state interval of the MOSFET 1 is made closer to the interval indicated by the inputted control signal.
(Fourth Embodiment)
A fourth embodiment is shown in
A signal output circuit 33 according to the fourth embodiment has a switch circuit 34 provided between the booster circuit 4 and the current mirror circuit 5 in the signal output circuit 21 according to the third embodiment. The switch circuit 34 is controlled by a logic circuit 35. As shown in
(Fifth Embodiment)
A fifth embodiment is shown in
The current mirror circuits 5 and 7 are configured similarly to those of the second embodiment. The switch circuit 34 shown in
The mirror ratio of the PNP transistors 5a and 5b in the current mirror circuit 5 is set to 1:10. When a collector current of a maximum of 200 μA flows at the PNP transistor 5b side, a collector current of 2 mA flows in the PNP transistor 5a side. Since the mirror ratio of the NPN transistors 7a and 7b in the current mirror circuit 7 is set to 1:20, a collector current of a maximum of 4 mA flows in the NPN transistor 7b side.
The transistor 39 is provided between the controlled power source voltage Vcp and the current mirror circuit 5. When the MOSFET 38 is turned off, the PNP transistor 39 is also turned off so that the controlled power source voltage Vcp is not supplied to the current mirror circuits 5 and 7. When the MOSFET 37 is turned on, the transistor 39 is also turned on so that the controlled power source voltage Vcp is supplied to the current mirror circuits 5 and 7.
Control signals A, B, C and D applied to the gates of the MOSFETs 28, 32, 38 and 8 in
In the time interval (2), in which the charging side of the rapid charge/discharge circuit 22 is operated, the control signal A is changed to the high level so that the transistor 29 is turned on to supply the charge current. A voltage indicated as BATT+Thr in correspondence to the time interval (2) corresponds to the threshold voltage set for the comparator 24 shown in
In the last time interval (5), in which the gate potential falls to 1V, only the control signal B is changed to the high level to rapidly discharge so that the gate potential is surely changed to the low level. The power supply to the current mirror circuit 5 is interrupted in performing the rapid charging in the time intervals (3) and (5) so that the current consumption is reduced. The control logic shown in
According to the fifth embodiment, during the time interval, in which the discharging side of the rapid charge/discharge circuit 22 is operated, the supply of the controlled power source voltage Vcp is interrupted thereby to reduce power consumption.
(Sixth Embodiment)
A sixth embodiment is shown in
A main part of the signal output circuit 33 is configured as an integrated circuit (IC) 40. The resistor 6R of the current source 6, the capacitor 9 and the MOSFET 1 are attached to the IC 40 from the external side. With this configuration, it is possible to trim the resistor 6R at an outside of the IC 40 and to adjust a resistance or capacitance by replacing the resistor 6R or the capacitor 9. As a result, the variation in the CR time constants is reduced, and the change rates of rise and fall are readily adjustable.
The examples of the PWM signal V(PWM), the gate potential V(GATE) of the MOSFET 1, the source potential V(OUT) and the load current I(OUT), which are actually measured in the circuit configuration shown in
The peak levels are also shown in
According to the sixth embodiment, the main part of the signal output circuit 33 is configured as the IC 40, and the resistor 6 and the capacitor 9 are externally connected to the IC 40. As a result, these circuit constants may be adjusted readily.
(Seventh Embodiment)
A seventh embodiment is shown in
In a signal output circuit 41 of the seventh embodiment, one more resistor 42 is connected to the IC 40 of the sixth embodiment. The resistor 42 is connected between the controlled power source voltage Vcp and the gate of the MOSFET 1. The resistor 42 and the resistor 6R are assumed to have resistances R1 and R2, respectively. When the gate potential rises, the charge current flows through the resistor 42. As a result, the charging is performed at a time constant determined by R1 and C. When the gate potential falls, the current mirror circuit 7 operates. As a result, the discharging is performed at a time constant determined by R1//R2 and C. The discharge time constant at the fall time is independently adjustable as indicated by (c) in
(Eighth Embodiment)
An eighth embodiment is shown in
A current source 47 is connected between the power source voltage Vcc and the switch circuit 8 in place of the PNP transistor 5b. A transistor (not shown) forming the current source 47 also forms a mirror pair with the transistor forming the current source 44. The controlled poser source voltage Vcp is supplied to a non-inverting input terminal of an amplifier 48 forming a differential amplifier circuit. The gate of the MOSFET 1 is connected to an inverting input terminal of the amplifier 48.
An output terminal of the amplifier 48 is connected to a non-inverting input terminal of an amplifier of a next stage. An emitter of the NPN transistor 45 is connected to an inverting input terminal of the amplifier 49. An output terminal of the amplifier 49 is connected to a base of the transistor 45. The current source 44, the amplifier 49, the NPN transistor 45 and the resistor 46 thus form a voltage-current converter circuit 100. The conversion circuit 100, the amplifier 48 and the current mirror circuit 5a form a current source (current generator circuit) 101.
In operation of the eighth embodiment, the amplifier 48 outputs to the amplifier 49 a voltage signal, which corresponds to a difference between the controlled power source voltage Vcp and the gate potential of the MOSFET 1. The amplifier 49 operates to supply a current I1(t) in correspondence to the voltage signal of the amplifier 49. It is assumed that a mirror ratio of the current source 44 and the PNP transistor 5a is 1:α, a mirror ratio of the current sources 44 and 47 is 1:1, an amplification gain of the amplifier 48 is β, a mirror ratio of the current mirror circuit 7 is 1:γ, a current supplied to the gate of the MOSFET 1 through the PNP transistor 5a is I2(t) and the gate potential of the MOSFET 1 is Vg. It is further assumed that the gate-source capacitance of the MOSFET is C and a charge time relative to the gate is t. The following equations hold with these assumptions.
I1(t)={Vcp−Vg(t)}×β/R (2)
I2(t)=I1(t)×y={Vcp−Vg(t)}×β×γ/R (3)
If α=β×γ, I2(t)={Vcp−Vg(t)}×α/R (4)
C×Vg(t)=I2(t)×t (5)
Vg(t)=I2(t)×t/C=Vcp×{1/(1+CR/αt)} (6)
If both terms are integrated, the gate potential Vg is expressed as follows.
Vg=Vcp×[1−exp{−α/(CR)}] (7).
The foregoing operation is performed at the time of switching of the switch circuit 8 from the on-state to the off-state. When the switch circuit 8 is switched from the off-state to the on-state, the gate of the MOSFET 1 is discharged by operation of the current mirror circuit 7 and the current source 101.
According to the eighth embodiment, as described above, the amplifier 48 outputs to the amplifier 49 the voltage signal corresponding to the difference between the controlled power source voltage Vcp and the gate potential Vg of the MOSFET 1. The amplifier 49 supplies the resistor 46 with the current corresponding to the voltage signal. Thus, in the similar manner as in the first embodiment, the gate of the MOSFET 1 is charged and discharged at the time constant CR.
(Ninth Embodiment)
A ninth embodiment is shown in
In a signal output circuit 50, a current mirror circuit 51 formed of a mirror pair of two PNP transistors 51a and 51b is connected to the controlled power source voltage Vcp side. Collectors of the PNP transistors 51a and 51b are connected to collectors of NPN transistors 52b and 53b, respectively. Bases of the PNP transistors 51a and 51b are connected to a collector of the PNP transistor 51a. A collector of the PNP transistor 51b and a collector of the NPN transistor 53b are connected to the gate of the MOSFET 1.
The NPN transistors 52b and 53b form mirror pairs with NPN transistors 52a and 53a, respectively, thereby to provide control current mirror circuits 52 and 53 connected to the ground side. Bases of the NPN transistors 52a and 52b are connected to a collector of the NPN transistor 52a. Bases of the NPN transistors 53a and 53b are connected to a collector of the NPN transistor 53a. For example, a mirror ratio of the current mirror circuits 51 and 53 is set to 1:20 and a mirror ration of the current mirror circuit 52 is set to be 1:1.
Collectors of the NPN transistor 52a and 53a are connected to collectors of PNP transistors 54b and 54c, respectively. The PNP transistors 54b and 54c are in a mirror pair with the PNP transistor 54a to form a current mirror circuit 54. Emitters of the PNP transistors 54a to 54c are all connected to the voltage Vcc. A collector of the PNP transistor 54a is connected to bases of the PNP transistors 54a to 54c and grounded through a variable resistor 55.
Since mirror currents, which flow in the current mirror circuits 52 and 53, are controlled by the current mirror circuit 54, the mirror currents of the current mirror circuits 52 and 53 are determined by a resistance of the resistor 55 and an output voltage of a differential amplifier 61. For example, it is so set that the mirror current of a maximum of about 100 μA flows in the PNP transistor 51a side.
The controlled power source voltage Vcp is supplied to a non-inverting input terminal of an amplifier 58 through a resistor 56. The gate of the MOSFET 1 is connected to an inverting input terminal of the amplifier 58 through a resistor 57. The non-inverting input terminal is connected to the ground through a resistor 59, and the non-inverting input terminal is connected to an output terminal of the amplifier 58 through a resistor 60. The output terminal is connected to a base of a NPN transistor 73. A collector of the NPN transistor 73 is connected to the collector of the PNP transistor 54a. An emitter of the NPN transistor 73 is connected to a resistor 55. Thus, a differential amplifier circuit 61 is formed by the amplifier 58 and associated components.
N-channel MOSFETs 62 and 63 are connected in parallel between the collectors and the emitters of the NPN transistor 52a and 53a, respectively, as control part. A gate of the MOSFET 63 is connected to a signal input terminal IN, and a gate of the MOSFET 62 is connected to the signal input terminal IN through an output terminal of a NOT gate 64.
A series circuit of a PNP transistor 65 and a N-channel MOSFET 66 is connected between the controlled power source voltage Vcp and the ground. A common junction (collector of the PNP transistor 65 and drain of the MOSFET 66) is connected to the gate of the MOSFET 1. A series circuit of resistors 67 and 68 is connected between the power source of the voltage VB and the ground. A common junction of the resistors 67 and 68 is connected a non-inverting input terminal of a comparator 69. The source of the MOSFET 1 is connected to an inverting input terminal of the comparator 69. An output terminal of the comparator 69 is connected to one input terminals of OR gates 70 and 71.
The other input terminal of the OR gate 70 is connected to an output terminal of a NOT gate 64. The other input terminal of the OR gate 71 is connected to the input terminal IN. An output terminal of the OR gate 70 is connected to the base of the PNP transistor 65. An output terminal of the OR gate 71 is connected to the gate of the MOSFET 66 through the NOT gate 72. The current mirror circuit 54, the resistor 55 and the operational amplifier 61 form a current source (current generator circuit) 102.
The operation of the ninth embodiment is shown with reference
When the PWM signal applied to the input terminal IN is changed to a high level as indicated by (a), the current mirror circuits 52 and 53 are turned on and off, respectively. Since the current mirror circuit 51 is turned on, the gate of the MOSFET 1 is charged and the gate potential Vg rises as indicated by (b) in
Ic=α×(Vcp−Vg)/R (8)
The source potential Vs indicated by (c) also rises as the gate potential Vg rises. When it rises above a reference voltage set by the resistors 67 and 68, the output level of the comparator 69 changes from the high level to the low level as indicated by (d). An output level of the OR gate 70 becomes low and the PNP transistor 65 is turned on as indicated by (e) thus forming a rapid charge path. As a result, the gate of the MOSFET 1 is rapidly charged. In the course of rising of the gate potential Vg of the MOSFET 1, an output voltage of the differential amplifier circuit 61 (emitter voltage of the NPN transistor 73) falls. Since the constant current value is decreased, the current, which flows to the gate of the MOSFET 1 through the current mirror circuits 51 and 54, is also decreased.
When the PWM signal at the input terminal IN is changed to the low level from the high level, the PNP transistor 65 is turned off as indicated by (e). The rapid charge path is interrupted and the output level of the OR gate 71 becomes low. The MOSFET 66 is turned on to form the rapid discharge path as indicated by (f), and the gate potential of the MOSFET 1 is rapidly decreased. Since the current mirror circuits 51 and 53 are turned off and on, respectively, discharging through the NPN transistor 53b is performed at the same time. Since the source potential Vs falls as the gate potential Vg falls, the output level of the comparator 69 is changed to a high level. The MOSFET 66 is thus turned off and the rapid discharge path is interrupted. The discharging is performed by only the current mirror circuit 53 thereafter. When the gate potential of the MOSFET 1 becomes low, the original state is restored.
According to the ninth embodiment described above, the differential amplifier circuit 61 outputs to the collector of the PNP transistor 54a the differential voltage between the controlled power source voltage Vcp and the gate potential Vg of the MOSFET 1. The charge current supplied to the gate of the MOSFET 1 through the current mirror circuits 52 and 54 is thus controlled. The comparator 69 compares the source potential of the MOSFET 1 with the reference voltage set in accordance with the power source voltage VB so that the formation of the rapid charge path and the rapid discharge path are formed by the output signal of the comparator 69. Since the source potential of the MOSFET 1 indicates the on-state of the MOSFET 1, the charge/discharge current is increased for an appropriate interval by controlling the formation of the rapid charge/discharge path based on a result of comparison of the source potential with the reference voltage.
(Tenth Embodiment)
A tenth embodiment is shown in
A signal output circuit 81 according to the tenth embodiment is different from the first embodiment shown in
(Eleventh Embodiment)
An eleventh embodiment is shown in
(Twelfth Embodiment)
A twelfth embodiment is shown in
A signal output circuit 83 of the twelfth embodiment has a constant voltage circuit 84 between the booster circuit 4 the current mirror circuit 5. That is, a series circuit of a current source 85 and a Zener diode 86 is connected between the booster circuit 4 of the controlled power source voltage Vcp and the power source VB. A common junction between the booster circuit 4 and the power source VB is connected to a base of a NPN transistor 87. A collector of the NPN transistor 87 is connected to the booster circuit 4 and an emitter of the same is connected to the current mirror circuit 5 (emitters of the PNP transistors 5a and 5b).
The power source voltage supplied to the current mirror circuit 5 is regulated to VB+Vz−VF, in which Vz indicates a Zener voltage of the Zener diode 86. The current mirror circuit 5 is thus supplied with a power source voltage, which is higher than the drain potential of the MOSFET 1 by a voltage Vz-VF. The MOSFET 1 is thus driven stably.
(Thirteenth Embodiment)
A thirteen embodiment is shown in
A signal output circuit 91 of the thirteenth embodiment is configured such that the light 2 is driven by a P-channel MOSFET (switching element) 92 at the high side. The MOSFET 92 is connected between the power source of the power source voltage VB and the light 2. A capacitor 93 is connected between a source and a gate of the MOSFET 92. A current mirror circuit 94 is provided at the power source voltage VB side and a current mirror circuit 95 is provided at the ground side. One current path of the current mirror circuit 94 is connected to the gate of the MOSFET 92 and a current source 96. The current source 96 has a part, which also forms a part of the current mirror circuit 95. The other current path of the current mirror circuit 94 is connected to the other current path of the current mirror circuit 95 through a switch circuit (control part) 97.
The signal output circuit 91 is configured in detail as shown in
The thirteenth embodiment operates as follows. When the PWM signal is at a low level, a high level signal, which is an inverse of the low level, is applied to the gate of the MOSFET 971 Since the current mirror circuit 94 is turned on, the gate potential of the MOSFET 92 is a high level, which is lower than the power source voltage VB by an emitter-collector voltage of the PNP transistor 94b. The MOSFET 92 is thus in the off-state. The capacitor 93 is in the charged state.
When the PWM signal is changed to a high level, the current mirror circuit 94 is turned off. The gate potential of the MOSFET 92 is changed to a low level by operation of the current mirror circuit 95. In this operation, the capacitance C between the gate and the source of the MOSFET 92 including the capacitor 93 is charged at a CR time determined by a resistance of the resistor 96R. When the gate potential falls to the low level (finally a voltage corresponding to VF of the NPN transistor 95a), the MOSFET 92 is turned on to supply a current to the light 2.
When the PWM signal is changed to the low level from this state, the current mirror circuit 94 is turned on. A current flows to the gate of the MOSFET 92 to raise the gate potential. The capacitance C between the gate and the source of the MOSFET 92 is discharged at the time constant CR. As described above, the same advantage as the first embodiment will be provided, even if the signal output circuit 91 of the thirteenth embodiment is configured to drive the light 2 at the high side.
(Fourteenth Embodiment)
A fourteenth embodiment is shown in
A signal output circuit 111 according to the fourteenth embodiment has additional circuits in an integrated circuit (IC) 112. A series circuit of a current source 113 and a switch circuit 114, which are both minute charge current supply part, is connected between the output terminal of the booster circuit 4 and the gate of the MOSFET 1. A series circuit of a switch circuit 115 and a current source 116, which are both minute discharge current output part, is connected between the gate of the MOSFET 1 and the ground. The amount of current supplied from the current source 113 is set to be smaller than that supplied through the current source 6. The amount of current supplied from the current source 116 is set to be smaller than that supplied when the current mirror circuit 5 operates.
A logic circuit 117 is provided in place of the logic circuit 35. A comparator 118 is added to compare the source potential of the MOSFET 1 with a threshold voltage Vth3. In the fourteenth embodiment, a threshold voltage applied to a non-inverting input terminal of the comparator 23 is indicated as Vth2, a threshold voltage VB+Vref, which is determined by a voltage Vref applied to an inverting input terminal of the comparator 24, is indicated as Vth1. The relation among these three threshold voltages are Vth1>Vth2>Vth3. The signals applied to the logic circuit 117 from the comparators 24, 23 and 118 are indicated as IN1, IN2 and IN3. The logic circuit 117 controls on and off of the switch circuits 114, 34, 8 and 115 by control signals A, B, E and F, respectively. The logic circuit 117 further controls the rapid charge circuit 22C and the rapid discharge circuit 22D by control signals C and D, respectively. In this embodiment, the current source 113, the switch circuits 114, 115, the current source 116, the logic circuit 117 and the comparators 24 and 118 form current change mitigation part (control part).
The operation of the fourteenth embodiment is described below with reference to
<Charge Time Operation>
When the PWM signal becomes high, the logic circuit 117 changes the control signal D to the low level to stop the operation of the rapid discharge circuit 22D. The logic circuit 117 also changes the control signal F to the low level to turn off the switch circuit 115. From this time point to a time point, at which the source potential Vs of the MOSFET 1 rises above the threshold voltage Vth2, the control signal A is changed to the high level to turn on the switch circuit 14. The capacitor 9 is thus charged by the current source 113. In this charge time, the MOSFET 1 turns on with its gate potential Vg rising to exceed the on-threshold voltage. The current Il supplied to the light 2 thus starts to flow very gradually.
When the source potential Vs exceeds the threshold voltage Vth2 with the input signal IN2 being at the high level, the logic circuit 117 changes the control signal B to the high level to turn on the switch circuit 34. The capacitor 9 is thus charged through the current source 6 (transistor 5a and resistor 6R). When the gate potential of the MOSFET 1 exceeds the threshold voltage Vth1 with the input signal IN1 being at the high level, the logic circuit 117 changes the control signals B and C to the low level and the high level, respectively, to operate the rapid charge circuit 22C and charge the gate capacitance of the MOSFET 1 rapidly.
<Discharge Time Operation>
When the PWM signal becomes low, the logic circuit 117 changes the control signal C to the low level to stop the operation of the rapid charge circuit 22C. From this time point to a time point, at which the source potential Vg of the MOSFET 1 falls below the threshold voltage Vth1, the control signal D is changed to the high level to operate the rapid discharge circuit 22D. The gate capacitance including the capacitor 9 is thus discharged rapidly by the rapid discharge circuit 22D.
When the gate potential Vg of the MOSFET 1 falls below the threshold voltage Vth1 with the input signal IN1 being at the low level, the logic circuit 117 changes the control signal D to the low level to stop the operation of the rapid discharge circuit 22D. The logic circuit 117 further changes the control signals B and E to the high level to discharge the gate capacitance including the capacitor 9 by the current mirror circuits 5 and 7. When the source potential Vs falls below the threshold voltage Vth2 with the input signal IN1 being at the low level, the control signals B and E are set to the low level and the control signal F is set to the high level. Then the switch circuit 115 is turned on to discharge gradually the gate capacitance by the current source 116. As a result, the change in the waveform becomes very gradual at the time of stopping supply of the current to the light 2. When the source potential falls below the threshold voltage Vth3 with the input signal IN3 being at the low level, the logic circuit sets the control signal D to the high level to operate the rapid discharge circuit 22D.
In
According to the fourteenth embodiment, the current change mitigation part 119 operates to mitigate the change of the current at the time of starting supply of the charge current to the gate of the MOSFET 1 and at the time of ending flow of the discharge current from the gate. Specifically, supply of the charge current is started through the current source of a smaller charge current from the state of stopping the operation of the current mirror circuit 5. The operation of the current mirror circuit 5 is stopped when the level of the source voltage Vs f the MOSFET 1 falls below the threshold value Vth2. Thus, the discharge current flows through the current source 116, which allows only a smaller discharge current. As a result, the current waveform is controlled to change gradually at the time of starting the current supply to the light 2 and at the time of ending the current supply to the light 2.
(Fifteenth Embodiment)
A fifteenth embodiment is shown in
A signal output circuit 111A of the fifteenth embodiment is different only in that the non-inverting input terminal of the comparator 118 formed as an integrated circuit (IC) 112A is not connected to the source of the MOSFET 1 but is connected to the gate of the MOSFET 1. As shown in
(Sixteenth Embodiment)
A sixteenth embodiment is shown in
A signal output circuit 121 has the following configuration as the control part in place of the current mirror circuit 7. A series circuit of a NPN transistor 122 and a resistor 123 (resistance R1) is connected between the MOSFET 1 and the ground. A base and an emitter of the NPN transistor 122 are connected to an output terminal and a non-inverting input terminal of an operational amplifier 124, respectively. The collector of the PNP transistor 5b is connected to the ground through a resistor 125 (resistance R2) and to a non-inverting input terminal of the operational amplifier 124.
The operation of the sixteenth embodiment is described below. It is assumed that a current ratio a between the PNP transistor 5a (collector current I1) and the PNP transistor 5b (collector current 12) is set to satisfy I1=α×I2. When the PWM signal is at the high level and the MOSFET 8T is turned on, the potential V+ at the non-inverting input terminal of the operational amplifier 124 is at a ground level and the NPN transistor 122 is turned off. When the PWM signal is at the low level and the MOSFET 8T is turned off, the potential V+ at the non-inverting input terminal of the operational amplifier 124 is at a level equal to R2×I2. Assuming that an emitter current of the NPN transistor 122 is 13, the current 13 is defines as I3=12×R2/R1 because R1×I3=R2×I2. By setting a resistance ratio R2/R1 to 2a, the following equation holds.
I3=2 α×I2=2 α×I1/α=2×I1
Therefore, the gate capacitance is discharged through the NPN transistor 122 by flowing a current, which is two times of the current I1 supplied from the current source 6. Thus, the same advantage as the first embodiment is provided.
The present invention is not limited to the embodiments described and shown above. The embodiments may be modified as follows.
The capacitor 9 may be eliminated. Although the waveform of rising and falling of the gate potential depends on an individual gate capacitance of each MOSFET 1, it is not so adversary if variations are not so influential. The electric load may be a motor or an LED, which is other than the light 2.
In the twelfth embodiment, the anode of the Zener diode 86 may be connected tot he ground, if the potential reference of the constant voltage circuit 84 need not be set to the drain voltage. In the thirteenth embodiment, one terminal of the capacitor 93 may be connected to the power source of the power source voltage VB without connection to the source of the MOSFET 92. Only the gate-source capacitance of the MOSFET 92 may be used without using the capacitor 93. In the fourteenth and the sixteenth embodiments, the rapid charge/discharge circuit 22 may be eliminated. The switch circuit 34 may be eliminated.
Number | Date | Country | Kind |
---|---|---|---|
2010-3878 | Jan 2010 | JP | national |
2010-139306 | Jun 2010 | JP | national |
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Entry |
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Office Action mailed Feb. 7, 2012 in corresponding JP Application No. 2010-139306 (and English translation). |
Number | Date | Country | |
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20110169475 A1 | Jul 2011 | US |