JP2004104645A - Triangular wave generating device, pulse width modulation signal generating device and external synchronization/internal synchronization/asynchronization switching device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To generate a triangular wave that goes up and down at constant inclination. <P>SOLUTION: A triangular wave generating device is provided with a capacitor, a current source for outputting constant current, a resetting voltage output circuit, a charging or discharging control circuit and a charging/discharging circuit and outputs a voltage waveform of the capacitor as a triangular wave. The resetting voltage output circuit receives a pulse signal, synchronizes with a rise or a fall of a pulse signal, outputs first resetting voltage for a prescribed period shorter than one cycle of the pulse signal, and outputs a second resetting voltage after the elapse of the prescribed period. The charging or discharging control circuit receives the first resetting voltage to output instant discharge voltage and receives the second resetting voltage to output discharge prevention voltage. The charging/discharging circuit receives the discharge prevention voltage, supplies the constant current from the current source to a capacitor, stores electrical charge in the capacitor, also receives the instant discharge voltage and discharges the electrical charge stored in the capacitor at inclination regarded to be perpendicular to a time base. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a triangular wave generator. Further, the present invention relates to a pulse width modulation signal generation device that generates a pulse width modulation signal used for controlling a power converter such as a converter. Further, the present invention relates to a switching device for operating a plurality of devices synchronously or asynchronously.
[0002]
[Prior art]
The triangular wave is used when a pulse width modulation signal (PWM signal) is generated by a triangular wave comparison method (for example, see Non-Patent Document 1). As a triangular wave generating device, a device that repeatedly charges and discharges a capacitor is conventionally known (for example, see Patent Documents 1 and 2).
[0003]
FIG. 9 shows an example of a conventional triangular wave generator. In the figure, a triangular wave generator 10 includes an output terminal 11, a comparator 12, switches SW1 and SW2, a voltage source 14 (voltage Vhi), a voltage source 16 (voltage Vlo), a current source S1 for supplying a constant current, It comprises resistors R1, R2, capacitors C1, C2, and an input terminal 18. In the figure, VCC is a power supply line, and VSS is a ground line. A connection node between the + input terminal of the comparator 12 and the capacitor C1 is referred to as a node A. The switches SW1 and SW2 switch according to the output voltage of the comparator 12. Specifically, when the voltage of the node A reaches Vhi, the output voltage of the comparator 12 switches from low level to high level, the switch SW1 switches from the voltage source 14 to the voltage source 16, and the switch SW2 turns off ( It switches from open to on. When the voltage at the node A decreases to Vlo, the output voltage of the comparator 12 switches from the high level to the low level, the switch SW1 switches from the voltage source 16 to the voltage source 14, and the switch SW2 switches from on to off. .
[0004]
FIG. 10 is an explanatory diagram showing a time change of the output voltage of the triangular wave generator of FIG. Hereinafter, the operation of the above-described triangular wave generator 10 will be described.
First, a case where a synchronization signal is not input will be described (FIG. 10A). Until immediately before time t0, the switch SW1 is connected to the voltage source 16 and the switch SW2 is on. Therefore, until immediately before time t0, the capacitor C1 has been discharged through the current source S1. At time t0, the voltage of the node A decreases to Vlo due to the discharge of the capacitor C1. In synchronization with this, the output voltage of the comparator 12 switches from the high level to the low level, the switch SW1 switches to the voltage source 14, and the switch SW2 switches off. Therefore, the capacitor C1 starts to be charged by the power supply line VCC via the resistor R1. Therefore, the output voltage of the triangular wave generator 10, which is the voltage of the node A, increases.
[0005]
When the voltage at the node A reaches Vhi (time t1), the output voltage of the comparator 12 switches from the low level to the high level, the switch SW1 switches to the voltage source 16, and the switch SW2 switches on. Therefore, the capacitor C1 discharges through the current source S1 until the voltage at the node A decreases to Vlo. Therefore, the output voltage of the triangular wave generator 10, which is the voltage of the node A, decreases. When the voltage of the node A decreases to Vlo (time t2), the operation from time t0 to time t2 is repeated thereafter.
[0006]
Next, a case where a synchronization signal is externally input to the input terminal 18 will be described (FIG. 10B). Until immediately before time t0, the switch SW1 is connected to the voltage source 16 and the switch SW2 is on. Therefore, until immediately before time t0, the capacitor C1 is discharging, and the voltage of the node A is decreasing toward Vlo. At time t0, the synchronization signal switches from the high level to the low level. In synchronization with this falling edge, the voltage at the node A transiently drops to Vlo through the capacitors C1 and C2. Therefore, at time t0, the switch SW1 is switched to the voltage source 14, and the switch SW2 is switched off. Therefore, the capacitor C1 starts to be charged by the power supply line VCC via the resistor R1, and the output voltage of the triangular wave generator 10 rises.
[0007]
At time t3, the voltage of the node A transiently rises to Vhi from the input terminal 18 through the capacitors C1 and C2 due to the rise of the synchronization signal. In synchronization with this, the switch SW1 is switched to the voltage source 16 side, and the switch SW2 is switched on. For this reason, the capacitor C1 discharges through the current source S1, and the output voltage of the triangular wave generator 10 decreases. Thereafter, at time t4, when the synchronization signal falls, the operation from time t0 to time t4 is repeated thereafter.
[0008]
[Patent Document 1]
JP-A-9-172355 (Section 4-5, FIG. 1)
[Patent Document 2]
JP-A-11-191725 (Section 4-5, FIG. 3)
[Non-patent document 1]
Linear Technology Corporation, LTC1504 Datasheet Internet <URL: http: // www. linear-tech. co. jp / datasheet / html / jp # pdf / j1504 # 7. pdf> (Section 1-5, FIG. 3)
[0009]
[Problems to be solved by the invention]
In the triangular wave generator 10 shown in FIG. 9, when synchronizing with an external synchronization signal, the voltage of the node A is instantaneously changed in synchronization with the rise and fall of the synchronization signal. For this reason, a protruding waveform is generated at the time of the upper peak and the lower peak of the triangular wave.
[0010]
Further, since the output is the voltage of the capacitor C1 which repeats charging and discharging, the output has an exponential waveform, so that the calculation of the frequency and the duty ratio becomes complicated.
Furthermore, the frequency of the output triangular wave differs between the case where synchronization is performed and the case where synchronization is not performed. That is, when a plurality of devices each having such a triangular wave generator are operated simultaneously without synchronization, the devices operate at different frequencies. In this case, noise and ripples occur due to interference between the devices.
[0011]
When a power converter or the like is controlled by a PWM signal, a dead time is required in each cycle of the PWM signal. This is necessary, for example, to prevent the saturation of the transformer in a single converter or to prevent a plurality of transistors that should be turned on alternately in a full bridge converter from being turned on at the same time. For this reason, when generating a PWM control signal by the triangular wave comparison method, it is necessary to provide a dead time in the PWM signal by providing a circuit (limiter or the like) different from the triangular wave generator. Accordingly, there has been a demand for a technique for adding a dead time to a PWM signal in a pulse width modulation signal generation device without providing a separate circuit from the triangular wave generation device.
[0012]
An object of the present invention is to provide a generator of a triangular wave that rises and falls at a constant inclination.
Another object of the present invention is to provide a technique for easily synchronizing the operating frequency of each device when a plurality of devices controlled by a PWM signal are operated simultaneously. Another object of the present invention is to provide a technique for adding a dead time to a PWM signal in a pulse width modulation signal generator by simply providing a simple circuit different from a triangular wave generator.
[0013]
[Means for Solving the Problems]
A triangular wave generating device according to a first aspect includes a capacitor, a current source that outputs a constant current, a reset voltage output circuit, a charge / discharge control circuit, and a charge / discharge circuit, and outputs a voltage waveform of the capacitor as a triangular wave.
The reset voltage output circuit receives the synchronization signal, and outputs a first reset voltage for a predetermined period shorter than one period of the synchronization signal in synchronization with a rising or falling edge of the synchronization signal, and after a lapse of the predetermined period, outputs a second reset voltage. Output voltage.
[0014]
The charge / discharge control circuit receives the first reset voltage and outputs an instantaneous discharge voltage, and receives the second reset voltage and outputs a discharge prevention voltage.
The charge / discharge circuit receives the discharge prevention voltage, supplies a constant current from the current source to the capacitor, and stores the charge in the capacitor. Further, the charge / discharge circuit receives the instantaneous discharge voltage and discharges the charge stored in the capacitor with a gradient that can be regarded as perpendicular to the time axis.
[0015]
In the triangular wave generator according to the second aspect, the predetermined period during which the reset voltage output circuit outputs the first reset voltage is longer than the time required for discharging the charge accumulated in the capacitor.
According to a third aspect of the present invention, the reset voltage output circuit includes a dead time signal generation circuit, a switch, and a second reset voltage output circuit.
Upon receiving the synchronization signal, the dead time signal generation circuit outputs a switch-on voltage for a predetermined period in synchronization with the rise or fall of the synchronization signal. The dead time signal generation circuit outputs a switch-off voltage after a predetermined period has elapsed.
[0016]
The switch is turned on in response to the switch-on voltage, and connects the charge / discharge control circuit to the supply source of the first reset voltage. The switch is turned off in response to the switch-off voltage.
The second reset voltage output circuit inputs the second reset voltage to the charge / discharge control circuit during the off period of the switch.
[0017]
In the triangular wave generator according to the fourth aspect, the synchronization signal is input from an external circuit.
According to a fifth aspect of the present invention, there is provided a triangular wave generator according to the fourth aspect, further comprising an internal oscillation circuit and a selection circuit. Note that the internal oscillation circuit generates a synchronization signal that can be adjusted to the same frequency as the frequency of the synchronization signal input from the external circuit. Further, the selection circuit causes a reset voltage output circuit to input either a synchronization signal input from an external circuit or a synchronization signal generated by an internal oscillation circuit.
[0018]
The pulse width modulation signal generating device according to claim 6 detects an output voltage of a device controlled by the pulse width modulation signal, and generates a pulse width modulation signal by using an internal triangular wave generation device. The pulse width modulation signal generation device includes a triangular wave generation device, a reference voltage source that outputs a reference voltage, an error amplifier circuit, a comparator, and a pulse width modulation signal output circuit.
[0019]
In the triangular wave generator according to the third aspect, the dead time signal generation circuit can output a voltage to a plurality of circuit elements.
The error amplifier circuit has a first input terminal for receiving an output voltage of the device and a second input terminal for receiving a reference voltage, and outputs a voltage obtained by amplifying a difference between the output voltage of the device and the reference voltage.
[0020]
The comparator has a third input terminal for receiving a triangular wave output from the triangular wave generator, and a fourth input terminal for receiving an output voltage of the error amplifier circuit. The comparator outputs a high-level voltage or a low-level voltage according to the difference between the triangular wave and the output voltage of the error amplifier circuit.
[0021]
The pulse width modulation signal output circuit has a fifth input terminal receiving the output voltage of the comparator and a sixth input terminal receiving the output voltage of the dead time signal generation circuit. The pulse width modulation signal output circuit outputs a low-level voltage as a pulse width modulation signal during a predetermined period during which the switch-on voltage is received, and outputs a high level or low level according to the output voltage of the comparator during the period during which the switch-off voltage is received. The level voltage is output as a pulse width modulation signal.
[0022]
An external synchronous / internal synchronous / asynchronous switching device according to claim 7 operates a plurality of devices each having an internal oscillation circuit for generating a synchronous signal and a triangular wave generating device in any of external synchronous, internal synchronous, and asynchronous. Here, the external synchronization is to operate a plurality of devices by using a synchronization signal input from an external circuit to any of the plurality of devices. In the internal synchronization, a plurality of devices are operated by a synchronization signal generated by any of the internal oscillation circuits of the plurality of devices. The non-synchronous operation causes each of the plurality of devices to be operated by a synchronization signal generated by an internal oscillation circuit in each of the plurality of devices.
[0023]
The triangular wave generator of each device is the triangular wave generator according to claim 3.
The external synchronous / internal synchronous / asynchronous switching device includes a common line connecting a plurality of devices to each other, and a switching circuit built in each of the plurality of devices.
The common wiring is for inputting a synchronization signal input from an external circuit and a synchronization signal generated by an internal oscillation circuit of any of the plurality of devices to a plurality of devices in common.
[0024]
Each switching circuit is connected to the triangular wave generator, the internal oscillation circuit, and the common wiring in each device, and receives one of a plurality of selection signals input from the outside. Each switching circuit performs an external synchronization operation in which a synchronization signal input from an external circuit is input to a triangular wave generator according to the level of a selection signal, and outputs a synchronization signal generated by an internal oscillation circuit of one of a plurality of devices as a triangular wave. Switching between an internal synchronous operation to be input to the generator and an asynchronous operation to input a synchronous signal generated by each internal oscillation circuit to each triangular wave generator in each device.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a first embodiment of the present invention. This embodiment corresponds to claims 1 and 2. In the figure, a triangular wave generator 20A includes a capacitor C3, a current source S2, a diode D1, a comparator 22, a current source S3, a resistor Rt, a transistor Tr, a capacitor C4, an input terminal 23, and an output terminal 24. In the figure, VCC is a power supply line, and VSS is a ground line. The triangular wave generator 20A receives a synchronization signal generated by an external circuit (not shown) at an input terminal 23, and outputs a voltage at a connection node between the capacitor C3 and a negative input terminal of the comparator 22 from an output terminal 24. The external circuit is, for example, a pulse generator. The base current of the transistor Tr is Ib, the constant current supplied by the current source S2 is Is, the constant current supplied by the current source S3 is It, and the resistance value of the resistor Rt is Rt.
[0026]
Hereinafter, the correspondence between the claims and the present embodiment will be described. In addition, the following correspondence shows one interpretation for reference, and does not limit the present invention.
The capacitor described in the claims corresponds to the capacitor C3.
The current source described in the claims corresponds to the current source S2.
The reset voltage output circuit corresponds to the current source S3, the resistor Rt, the transistor Tr, the capacitor C4, and the input terminal 23.
[0027]
The output of the reset voltage output circuit corresponds to the voltage of the connection node between the resistor Rt and the + input terminal of the comparator 22.
The first reset voltage in the claims corresponds to the voltage of the ground line VSS.
The second reset voltage in the claims corresponds to a voltage corresponding to It × Rt.
[0028]
The charge / discharge control circuit described in the claims corresponds to the comparator 22.
The charge / discharge circuit described in the claims corresponds to the diode D1.
FIG. 2 is an explanatory diagram showing the time change of the voltage of each part of the triangular wave generator 20A. Hereinafter, the operation of the above-described triangular wave generator 20A will be described with reference to FIGS. At time t0, the synchronization signal switches to a high level. In synchronization with this, the base current Ib flows through the transistor Tr instantaneously. Therefore, the transistor Tr is turned on, and the + input terminal of the comparator 22 is connected to the ground line VSS. Therefore, the output of the comparator 22 drops to the negative saturation voltage (the instantaneous discharge voltage described in the claims), the diode D1 turns on, and the capacitor C3 discharges. That is, the output voltage of the triangular wave generator 20A decreases.
[0029]
At time t1, the capacitor C3 is almost completely discharged. At this time, the transistor Tr is on. That is, after the time t1, the output of the triangular wave generator 20A is constant at 0 V until the transistor Tr is turned off.
At time t2, the transistor Tr is turned off due to the decrease in the base current Ib. Therefore, the voltage of the + input terminal of the comparator 22 increases to It × Rt. As a result, the output voltage of the comparator 22 rises to a positive saturation voltage (discharge prevention voltage described in claims), and the diode D1 turns off. Therefore, the capacitor C3 is charged by the constant current Is supplied from the current source S2 until the transistor Tr is turned on again at the rise of the synchronization signal (time t3). Thereafter, the operation from time t0 to time t3 is repeated.
[0030]
Note that the base current Ib flowing from time t0 decreases exponentially according to a time constant determined by the capacitance of the capacitor C4 and the resistance between the base and the emitter of the transistor Tr. In addition, the transistor Tr is on while the base current Ib is equal to or greater than the predetermined value. Therefore, as the capacitance of the capacitor C4 is larger, the base current Ib gradually decreases, and the time during which the transistor Tr is on becomes longer. In the present embodiment, the capacitor C3 is set so that the period in which the base current Ib is equal to or greater than the predetermined value (the period in which the transistor Tr is on, that is, the predetermined period) is longer than the discharging time of the capacitor C3. The capacity of C4 is set.
[0031]
If the peak voltage of the triangular wave is Vpeak, the capacitance of the capacitor C3 is Cm, and the length of the off period of the transistor Tr is toff, the peak voltage Vpeak is given by the following equation.
Vpeak = Is × toff ÷ Cm (1)
By modifying the above equation, the following equation holds.
[0032]
Cm = Is × toff ÷ Vpeak (2)
The capacitance Cm of the capacitor C3 is set large enough so that the following equation is satisfied.
Cm ≧ Is × toff ÷ (It × Rt) (3)
Here, the following expression is established by the expressions (2) and (3).
[0033]
Vpeak ≦ It × Rt (4)
Therefore, during the off period of the transistor Tr, the charging voltage of the capacitor C3 becomes higher than the voltage given by the product of the constant current It and the resistance Rt, and the comparator 22 outputs a negative voltage and the capacitor C3 discharges. There is no. That is, during the off period of the transistor Tr, the capacitor C3 continues to be charged by the constant current Is, and the voltage of the output terminal 24 keeps increasing with a constant slope.
[0034]
As described above, in the triangular wave generator 20A of the present embodiment, the voltage of the capacitor C3 charged by the constant current Is is output. For this reason, a triangular wave whose rising period is linear can be generated.
Further, in synchronization with the turning on of the transistor Tr due to the rise of the synchronization signal, the output of the comparator 22 becomes a negative saturation voltage. For this reason, the electric charge accumulated in the capacitor C3 is biased by the negative saturation voltage and rapidly discharged, so that the voltage waveform of the capacitor C3 at the time of discharging becomes substantially perpendicular to the time axis. That is, a triangular wave whose falling period is linear can be generated. As a result, a protruding waveform does not occur at the time of the upper peak and the lower peak of the triangular wave.
[0035]
Further, the capacitance of the capacitor C4 was set such that the on-period of the transistor Tr was longer than the discharge time of the capacitor C3. For this reason, a triangular wave having a dead time can be generated during a period from the falling period to the transition to the rising period. The length of the dead time can be adjusted by appropriately selecting the capacitance value of the capacitor C4. For example, the capacitance of the capacitor C4 may be increased, and the on-period of the transistor Tr may be equal to the half period of the synchronization signal. In this case, the dead time of the triangular wave is substantially equal to the half period of the synchronizing signal, and the rising period of the triangular wave becomes shorter, so that the amplitude of the triangular wave becomes smaller.
[0036]
FIG. 3 shows a second embodiment of the present invention. This embodiment corresponds to claims 1 to 3. The same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted. The triangular wave generator 20B shown in FIG. 3 is the same as the triangular wave generator 20A of the first embodiment except that a dead time signal generator 25 is formed instead of the capacitor C4.
[0037]
The dead time signal generation circuit 25 includes an input terminal 23, a resistor Rd, a capacitor Cd, an inverter 56, an AND gate 58, and a dead time signal output terminal 25a. A connection node between the resistor Rd and the capacitor Cd is referred to as a node B.
《Correspondence with Claims》
Hereinafter, the correspondence between the claims and the present embodiment will be described. Note that the correspondence shown below is an interpretation for reference, and does not limit the present invention.
[0038]
The reset voltage output circuit corresponds to the dead time signal generation circuit 25, the transistor Tr, the current source S3, and the resistor Rt.
The switch-on voltage described in the claims corresponds to the high-level voltage output by the AND gate 58.
[0039]
The switch-off voltage described in the claims corresponds to the low-level voltage output by the AND gate 58.
The switch described in the claims corresponds to the transistor Tr.
The supply source of the first reset voltage in the claims corresponds to the ground line VSS.
The second reset voltage output circuit corresponds to the current source S3 and the resistor Rt.
[0040]
FIG. 4 is an explanatory diagram showing the time change of the voltage of each part of the triangular wave generator 20B. Hereinafter, the operation of the above-described triangular wave generator 20B will be described with reference to FIGS.
Immediately before time t0, the capacitor Cd is discharged, and the voltage of the node B is at the same level as the ground line VSS. Therefore, the inverter 56 outputs a high-level voltage. The AND gate 58 outputs a low-level voltage because one input terminal receives a low-level synchronization signal from the input terminal 23.
[0041]
At time t0, the synchronization signal switches to a high level. In synchronization with this, the output voltage of the inverter 56 switches to a high level, and the output voltage of the AND gate 58 also switches to a high level, so that the transistor Tr turns on. Therefore, similarly to the triangular wave generator 20A of the first embodiment, the capacitor C3 discharges at an inclination that can be regarded as substantially perpendicular to the time axis. At the same time, the capacitor Cd starts to be charged, and the voltage at the node B increases exponentially according to a time constant determined by the capacitance of the capacitor Cd and the resistance value of the resistor Rd.
[0042]
At time t1 (not shown), the capacitor C3 is completely discharged, and the voltage at the output terminal 24 becomes 0V. Since the electric charge accumulated in the capacitor C3 is biased by the negative saturation voltage of the comparator 22 and is discharged rapidly, the time t1 is immediately after the time t0.
At time t2, the voltage of the node B reaches the threshold voltage of the inverter 56 (Vth in the figure) due to the charging of the capacitor Cd. Therefore, the output voltage of the inverter 56 switches to a low level, and the output voltage of the AND gate 58 also switches to a low level, so that the transistor Tr is turned off. Therefore, similarly to the first embodiment, the capacitor C3 starts to be charged, and the voltage of the output terminal 24 starts to increase. That is, during the period from time t1 to t2 (triangular wave dead time), the voltage of the output terminal 24 is constant at 0V.
[0043]
At time t3, the synchronization signal switches to a low level. In synchronization with this, the capacitor Cd starts discharging.
At time t4, the voltage of the node B decreases to the threshold voltage of the inverter 56 due to the discharge of the capacitor Cd. Therefore, the output voltage of the inverter 56 switches to a high level. Since the AND gate 58 receives a low-level synchronization signal from the input terminal 23 at one input terminal, the AND gate 58 continuously outputs a low-level voltage. Therefore, the transistor Tr is off after the time t4 after the time t2. That is, the capacitor C3 continues to be charged after the time t2 and also after the time t4.
[0044]
At time t5, the capacitor Cd is completely discharged. Thereafter, when the synchronization signal switches to the high level again (time t6), the operation from time t0 to time t5 described above is repeated thereafter.
In the present embodiment, the predetermined period corresponds to a period during which the transistor Tr is on, that is, a period during which the dead time signal generation circuit outputs a high-level voltage (from time t0 to time t2). are doing. Also, the time (from time t0 to time t2) until the voltage of the node B reaches the threshold voltage of the inverter 56 from the ground line VSS level is longer than the time required for discharging the capacitor C3 (from time t0 to time t1). The capacity of the capacitor Cd is set so as to be sufficiently long.
[0045]
As described above, also in the present embodiment, the same effects as those in the first embodiment can be obtained. In the present embodiment, the length of the period (dead time of the triangular wave) from time t1 to t2 can be adjusted by the capacitance of the capacitor Cd and the resistance value of the resistor Rd. That is, the larger the capacitance of the capacitor Cd, the more slowly the voltage at the node B increases. Therefore, the time (from time t0 to time t2) until the output voltage of the inverter 56 switches to a low level after the rise of the synchronization signal is long. Therefore, the dead time of the triangular wave becomes longer.
[0046]
FIG. 5 shows a third embodiment of the present invention. This embodiment corresponds to claims 1 to 3, and claim 6. The same parts as those in the first and second embodiments are denoted by the same reference numerals, and description thereof will be omitted. The pulse width modulation signal generator 26 shown in FIG. 5 includes an AND gate 58, an inverter 56, a triangular wave generator 20B, a comparator 28, an error amplifier 30, and a reference voltage source 32 that outputs a reference voltage Vb. It is configured.
[0047]
Hereinafter, the correspondence between the claims and the present embodiment will be described. Note that the correspondence shown below is an interpretation for reference, and does not limit the present invention.
The error amplifier circuit, the first input terminal, and the second input terminal described in the claims correspond to the error amplifier 30 and its negative input terminal and positive input terminal, respectively.
The comparator, the third input terminal, and the fourth input terminal in the claims correspond to the comparator 28 and the + input terminal and the − input terminal thereof, respectively.
[0048]
The pulse width modulation signal output circuit described in claims corresponds to the AND gate 58 and the inverter 56.
The fifth input terminal in the claims corresponds to an input terminal (not shown) of the AND gate 58 that receives the output voltage of the comparator 28.
The sixth input terminal in the claims corresponds to an input terminal (not shown) of the inverter 56.
[0049]
The pulse width modulation signal described in the claims corresponds to the output voltage of the AND gate 58.
FIG. 6 is an explanatory diagram showing an example of a time change of the PWM signal of FIG. Hereinafter, the operation of the above-described pulse width modulation signal generation device 26 will be described with reference to FIGS.
[0050]
Error amplifier 30 receives reference voltage Vb at a + input terminal, and receives an output voltage of a device (not shown) controlled by a PWM signal at a − input terminal. The error amplifier 30 amplifies the difference between the positive and negative input voltages and outputs the amplified difference as a feedback signal. The comparator 28 has a positive input terminal connected to the output terminal 24 (see FIG. 3) of the triangular wave generator 20B, and a negative input terminal connected to the output of the error amplifier 30. As shown in FIG. 6, the comparator 28 outputs a positive saturation voltage while the triangular wave voltage is higher than the feedback signal, and outputs a negative saturation voltage while the triangular wave voltage is lower than the feedback signal.
[0051]
The inverter 56 is connected to the dead time signal output terminal 25a (see FIG. 3) of the triangular wave generator 20B. Therefore, the output voltage of the inverter 56 (one input voltage of the AND gate 58) is at a low level during the dead time of the triangular wave, and is at a high level during a period excluding the dead time of the triangular wave.
In other words, the AND gate 58 outputs a low-level PWM signal regardless of the output voltage of the comparator 28 during the triangular dead time. The AND gate 58 outputs a high-level PWM signal if the output voltage of the comparator 28 is positive and a low-level PWM signal if the output voltage of the comparator 28 is negative during a period excluding the dead time of the triangular wave. Is output.
[0052]
In the pulse width modulation signal generator 26 described above, the triangular wave sharply falls from the maximum value to the minimum value (0 V) at the rising edge of the synchronization signal, as described above. For this reason, if the output voltage of the error amplifier 30 is positive, the output voltage of the comparator 28 always switches from positive to negative at the rising edge of the synchronization signal, so that the output voltage (PWM signal) of the AND gate 58 also changes from the high level. Switch to low level. Therefore, it is possible to easily trigger the PWM signal.
[0053]
The output voltage of the inverter 56 becomes low during the dead time of the triangular wave. Therefore, the AND gate 58 outputs a low-level PWM signal regardless of the output voltage of the comparator 28 during the dead time of the triangular wave. That is, if the pulse width modulation signal generation device is designed by the triangular wave comparison method using the triangular wave generation device 20B of the second embodiment, the PWM signal having the dead time can be easily generated without providing another circuit such as a limiter. Can be generated.
[0054]
FIG. 7 shows a fourth embodiment of the present invention. This embodiment corresponds to claims 1 to 5. In the figure, a single converter 36 includes an internal circuit 38, a pulse width modulation signal generation device 26 according to the third embodiment, an internal oscillation circuit 40, and a switch SW3 (selection circuit described in claims). I have. The single converter 36 is controlled by a PWM signal generated by the pulse width modulation signal generator 26. An external oscillation circuit 42 (an external circuit described in the claims) that generates a synchronization signal to be input to the pulse width modulation signal generation device 26 is arranged outside the device of the single converter 36. The external oscillation circuit 42 is, for example, a pulse generator.
[0055]
The internal circuit 38 has a transistor and a primary winding on the primary side (not shown). Further, the internal circuit 38 has a secondary winding, a smoothing capacitor, a smoothing reactor, and a diode on the secondary side (not shown). The detailed circuit diagram of the single converter is well known, and the description is omitted.
The internal oscillation circuit 40 generates a synchronization signal to be input to the pulse width modulation signal generation device 26. The internal oscillation circuit 40 can change the oscillation frequency of the synchronization signal, and detects the oscillation frequency of the synchronization signal output from the external oscillation circuit 42 (dotted arrow in the figure). Then, the internal oscillation circuit 40 oscillates at the same frequency as the external oscillation circuit 42. Further, even when the oscillation frequency of the external oscillation circuit 42 changes, the internal oscillation circuit 40 changes the oscillation frequency to the same as the oscillation frequency of the external oscillation circuit 42.
[0056]
When the single converter 36 described above is operated independently, the switch SW3 inputs the synchronization signal output from the internal oscillation circuit 40 to the triangular wave generator 20B (see FIG. 5) in the pulse width modulation signal generator 26. When the one-wheel converter 36 is operated in synchronization with another converter (not shown), the switch SW3 causes the synchronization signal output from the external oscillation circuit 42 to be input to the triangular wave generator 20B.
[0057]
As described above, in the present embodiment, the synchronization signal output from the internal oscillation circuit 40 has the same frequency as the synchronization signal output from the external oscillation circuit 42. For this reason, regardless of the single operation of the single converter 36 or the synchronous operation with another converter, the frequency of the synchronization signal input to (the triangular wave generator 20B of) the pulse width modulation signal generator 26 of the single converter 36. Will be the same. Therefore, the frequency and the amplitude of the triangular wave in the single converter 36 can be the same regardless of the single operation or the synchronous operation with another converter. Therefore, there is no possibility that the single converter 36 and the other converters operate at different frequencies from each other and interfere with each other. As a result, it is possible to prevent noise and ripple from being generated during the simultaneous operation of the single converter 36 and another converter.
[0058]
In addition, the single converter 36 is controlled by the PWM signal generated by the pulse width modulation signal generator 26. As described in the third embodiment, a dead time is always included in each cycle of the PWM signal. Accordingly, the saturation of the transformer (not shown) in the single converter 36 can be prevented.
FIG. 8 shows a fifth embodiment of the present invention. This embodiment corresponds to claim 7. FIG. 8 shows an example in which the external synchronous / internal synchronous / asynchronous switching device 44 of the present invention is applied to the simultaneous operation of a plurality of full bridge converters. In the figure, each of the full bridge converters 46A, 46B to 46N includes an internal circuit 48, the above-described pulse width modulation signal generation device 26, an internal oscillation circuit 50, and a switching circuit 52. It is controlled by a PWM signal generated by the device 26. The external synchronous / internal synchronous / asynchronous switching device 44 includes all the switching circuits 52 and a common wiring 54 that connects the switching circuits 52 to each other.
[0059]
The internal circuit 48 has, on the primary side, four transistors, two of which are alternately turned on, and a primary side winding (not shown). Further, the internal circuit 48 has a secondary winding, a smoothing capacitor, a smoothing reactor, and a diode on the secondary side (not shown). The detailed circuit diagram of the full-bridge converter is conventionally known, and thus the description is omitted.
[0060]
Each switching circuit 52 includes three-state buffers Bf1 and Bf2 and an inverter 56. Each switching circuit 52 receives selection signals A and B to N from the outside, respectively. Further, a synchronization signal generated by an external circuit (not shown) is input only to the switching circuit 52 of the full bridge converter 46A. This external circuit is, for example, a pulse generator.
[0061]
Hereinafter, the operation of the above-described external synchronous / internal synchronous / asynchronous switching device 44 when the full bridge converters 46A to 46N are operated in external synchronization, internal synchronization, or asynchronous operation will be described separately for each case.
(1) External synchronous operation
Each of the selection signals AN is set to a low level. At this time, in each of the full-bridge converters 46A to 46N, the output of the three-state buffer Bf1 becomes high impedance. The three-state buffer Bf2 of the full-bridge converter 46A inputs a synchronization signal from an external circuit to the pulse width modulation signal generation device 26 of the full-bridge converter 46A, and uses the common wiring 54 to connect the full-bridge converters 46B to 46f. It is also input to the 46N three-state buffer Bf2. The three-state buffers Bf2 of the full bridge converters 46B to 46N input the synchronization signal received via the common wiring 54 to the pulse width modulation signal generation device 26, respectively. Therefore, each of the full-bridge converters 46A to 46N is operated synchronously by a synchronous signal from an external circuit.
[0062]
(2) Internal synchronous operation
The selection signal A is set to a high level, and the other selection signals B to N are set to a low level. At this time, the outputs of the three-state buffers Bf1 of the full bridge converters 46B to 46N become high impedance. The three-state buffer Bf1 of the full-bridge converter 46A inputs the synchronization signal output from the internal oscillation circuit 50 to the pulse width modulation signal generator 26 of the full-bridge converter 46A, and uses the common wiring 54 to The signals are also input to the three-state buffers Bf2 of the converters 46B to 46N. The three-state buffers Bf2 of the full bridge converters 46B to 46N input the synchronization signal received via the common wiring 54 to the pulse width modulation signal generation device 26, respectively. That is, each of the full-bridge converters 46A to 46N is operated synchronously by the synchronization signal generated by the internal oscillation circuit 50 of the full-bridge converter 46A.
[0063]
(3) Asynchronous operation
Each of the selection signals AN is set to a high level. At this time, in each of the full bridge converters 46A to 46N, the three-state buffer Bf1 inputs the synchronization signal output from the internal oscillation circuit 50 to the pulse width modulation signal generation device 26. The output of each three-state buffer Bf2 becomes high impedance. That is, each of the full-bridge converters 46A to 46N is operated asynchronously by the synchronization signal generated by the internal oscillation circuit 50 in each of the full-bridge converters 46A to 46N.
[0064]
As described above, the external synchronous / internal synchronous / asynchronous switching device 44 of the present embodiment can easily switch between the external synchronous operation, the internal synchronous operation, and the asynchronous operation only by appropriately changing the levels of the selection signals A to N. Therefore, the operation frequency of each device (the full-bridge converters 46A to 46N in this example) can be easily synchronized by operating in external synchronization or internal synchronization. As a result, it is possible to prevent the full-bridge converters 46A to 46N from operating at different frequencies and interfere with each other, thereby preventing noise or ripple from occurring.
[0065]
Each of the full-bridge converters 46A to 46N is controlled by a PWM signal generated by the pulse width modulation signal generator 26. As described in the third embodiment, a dead time is always included in each cycle of these PWM signals. Therefore, in each of the full bridge converters 46A to 46N, it is possible to prevent a plurality of transistors (not shown) that should be turned on from being turned on at the same time.
[0066]
In the first embodiment described above, an example in which the capacitance of the capacitor C4 is set so that the time during which the transistor Tr is on is longer than the time required for discharging the capacitor C3, and a triangular wave having a dead time is generated. Stated. The present invention is not limited to such an embodiment. For example, the capacitance of the capacitor C4 may be set so that the time required for discharging the capacitor C3 is equal to the time during which the transistor Tr is on. In this case, there is no dead time, and the waveform is a triangular wave in which the falling period and the rising period are alternately switched.
[0067]
In the above-described first embodiment, an example has been described in which the triangular wave switches from the rising period to the falling period in synchronization with the rising edge of the synchronization signal. The present invention is not limited to such an embodiment. For example, an inverter may be connected in series between the capacitor C4 and the input terminal 23. In this case, the triangular wave switches from the rising period to the falling period in synchronization with the falling edge of the synchronization signal.
[0068]
In the above-described fifth embodiment, an example has been described in which the external synchronous / internal synchronous / asynchronous switching device 44 of the present invention is applied to simultaneous operation of a plurality of identical devices. The present invention is not limited to such an embodiment. The external synchronous / internal synchronous / asynchronous switching device of the present invention can be applied to, for example, simultaneous operation of a plurality of different devices such as a single converter and a full bridge converter.
[0069]
In the above-described fifth embodiment, an example in which all devices (full-bridge converters 46A to 46N) are operated in external synchronization, an example in which all devices are operated in internal synchronization, and an example in which all devices are operated asynchronously And said. The present invention is not limited to such an embodiment. For example, by setting the selection signals A and B to a low level and setting all other selection signals to a high level, the full-bridge converters 46A and 46B are operated externally synchronously, and the other full-bridge converters are operated asynchronously. Is also good.
[0070]
【The invention's effect】
The triangular wave generator according to the present invention can generate a triangular wave that rises and falls with a constant slope. The triangular wave generator according to the present invention can generate a triangular wave having a dead time. Therefore, if a pulse width modulation signal generator is designed by the triangular wave comparison method using the triangular wave generator of the present invention, a PWM signal having a dead time can be easily generated. In the external synchronous / internal synchronous / asynchronous switching device of the present invention, when a plurality of devices are operated simultaneously, the operating frequencies of the respective devices can be easily synchronized.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a triangular wave generator according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a time change of a voltage of each part of the triangular wave generator of FIG.
FIG. 3 is a circuit diagram illustrating a triangular wave generator according to a second embodiment of the present invention.
FIG. 4 is an explanatory diagram showing a time change of a voltage of each part of the triangular wave generator of FIG.
FIG. 5 is a circuit diagram showing a pulse width modulation signal generation device according to the present invention.
FIG. 6 is an explanatory diagram showing an example of a time change of the PWM signal of FIG. 5;
FIG. 7 is a block diagram showing a fourth embodiment of the present invention.
FIG. 8 is a block diagram showing an example in which the external synchronous / internal synchronous / asynchronous switching device of the present invention is applied to the operation of a plurality of full-bridge converters.
FIG. 9 is a circuit diagram showing an example of a conventional triangular wave generator.
10 is an explanatory diagram showing a time change of an output voltage of the triangular wave generator of FIG.
[Explanation of symbols]
10 Triangular wave generator
11 Output terminal
12 Comparator
14 Voltage source
16 Voltage source
18 Input terminal
20A, 20B triangular wave generator
22 Comparator
23 input terminal
24 output terminals
25 Dead time signal generation circuit
25a Dead time signal output terminal
26 Pulse width modulation signal generator
28 Comparator
30 Error amplifier
32 Reference voltage source
36 One-stone converter
38 Internal Circuit
40 Internal oscillation circuit
42 External oscillation circuit
44 External synchronous / internal synchronous / asynchronous switching device
46A-46N Full Bridge Converter
48 Internal Circuit
50 Internal oscillation circuit
52 Switching circuit
54 Common Wiring
56 inverter
58 AND GATE
Bf1, Bf2 Three-state buffers
C1, C2, C3, C4, Cd capacitors
R1, R2, Rd, Rt resistance
S1, S2, S3 current source
SW1, SW2, SW3 switch
Tr transistor

Claims (7)

In a triangular wave generator that outputs the voltage waveform of a capacitor as a triangular wave,
A current source that outputs a constant current;
Receiving a synchronization signal, outputting a first reset voltage for a predetermined period shorter than one cycle of the synchronization signal in synchronization with a rise or fall of the synchronization signal, and outputting a second reset voltage after the predetermined period has elapsed A reset voltage output circuit,
A charge / discharge control circuit that receives the first reset voltage, outputs an instantaneous discharge voltage, and receives the second reset voltage, and outputs a discharge prevention voltage;
In response to the discharge prevention voltage, the constant current is supplied to the capacitor to accumulate charge in the capacitor, and in response to the instantaneous discharge voltage, the charge accumulated in the capacitor can be regarded as perpendicular to the time axis. A triangular wave generator, comprising: a charge / discharge circuit that discharges at an inclination. The triangular wave generator according to claim 1,
The triangular wave generator according to claim 1, wherein the predetermined period during which the reset voltage output circuit outputs the first reset voltage is longer than a time required for discharging the accumulated charges. The triangular wave generator according to claim 2,
The reset voltage output circuit,
A dead time signal generation circuit that receives the synchronization signal, outputs a switch-on voltage in synchronization with a rise or fall of the synchronization signal, and outputs a switch-on voltage after the predetermined period, and ,
A switch that turns on in response to the switch-on voltage, connects the charge / discharge control circuit to a first reset voltage supply source, and turns off in response to the switch-off voltage;
A second reset voltage output circuit for inputting the second reset voltage to the charge / discharge control circuit during an off period of the switch. The triangular wave generator according to claim 1,
The triangular wave generator, wherein the synchronization signal is input from an external circuit. The triangular wave generator according to claim 4,
An internal oscillation circuit that generates a synchronization signal that can be adjusted to the same frequency as the frequency of the synchronization signal input from the external circuit,
A triangular wave generator, comprising: a selection circuit that inputs one of a synchronization signal input from the external circuit and a synchronization signal generated by the internal oscillation circuit to the reset voltage output circuit. A pulse width modulation signal generation device that detects an output voltage of a device controlled by a pulse width modulation signal and uses a triangular wave generation device included therein to generate the pulse width modulation signal,
The triangular wave generator according to claim 3, wherein the dead time signal generation circuit can output a voltage to a plurality of circuit elements.
A reference voltage source that outputs a reference voltage;
An error amplifier circuit having a first input terminal receiving the output voltage of the device and a second input terminal receiving the reference voltage, and outputting a voltage obtained by amplifying a difference between the output voltage of the device and the reference voltage;
A third input terminal that receives the triangular wave output from the triangular wave generator and a fourth input terminal that receives an output voltage of the error amplifier circuit, and according to a difference between the triangular wave and the output voltage of the error amplifier circuit, A comparator that outputs a high level voltage or a low level voltage,
A fifth input terminal for receiving an output voltage of the comparator and a sixth input terminal for receiving an output voltage of the dead time signal generation circuit; A pulse width modulation signal output circuit that outputs a high level or the low level voltage as the pulse width modulation signal in accordance with a level of an output voltage of the comparator during a period of outputting the signal as a width modulation signal and receiving the switch-off voltage; And a pulse width modulation signal generator. A plurality of devices each having an internal oscillation circuit for generating a synchronization signal and a triangular wave generation device are operated in external synchronization by a synchronization signal input from an external circuit to one of the plurality of devices, or one of the plurality of devices is operated. An external synchronous / internal synchronous / asynchronous switching device that operates in an internal synchronous manner by a synchronous signal generated by the internal oscillating circuit or asynchronously operates by a synchronous signal generated by the internal oscillating circuit in the plurality of devices. So,
The triangular wave generator is the triangular wave generator according to claim 3,
The plurality of devices are connected to each other so that a synchronization signal input from the external circuit and a synchronization signal generated by the internal oscillation circuit of any of the plurality of devices are commonly input to the plurality of devices. Common wiring,
The triangular wave generator, the internal oscillating circuit, and each connected to the common wiring in each of the plurality of devices, and each of the plurality of devices receives one of a plurality of selection signals input from the outside, An external synchronization operation in which a synchronization signal input from the external circuit is input to the triangular wave generator in accordance with a level of the selection signal, and a synchronization signal generated by the internal oscillation circuit of any of the plurality of devices is output from the triangle wave. A switching circuit for switching between an internal synchronous operation to be input to the generator and an asynchronous operation to input a synchronous signal generated by each of the internal oscillation circuits to each of the triangular wave generators in each of the devices. External synchronous / internal synchronous / asynchronous switching device.

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