JP5509624B2 - Signal generator - Google Patents

Description

  The present invention inputs a time axis signal (pulse) obtained by voltage / time conversion of at least one input quantity (voltage) and / or a time axis signal (pulse) generated from at least one oscillation circuit. The present invention relates to a signal generator that can generate a highly accurate control signal by delaying at least one of these time-axis signals.

Conventionally, there is a signal generator using an integration circuit (see Patent Document 1).
As shown in FIG. 15A, the signal generator 9 includes an analog quantity / digital quantity conversion circuit 91, a delay circuit 92, a first integration circuit 93, a second integration circuit 94, and a target signal output circuit 95. It consists of.

The analog quantity / digital quantity conversion circuit 91 generates a digital quantity D from the first analog quantity A ₁ (analog signal). The analog quantity / digital quantity conversion circuit 91 is configured to perform arithmetic processing such as digital filter processing on the digital quantity D.

The delay circuit 92 converts the digital amount into a time amount and shifts the operation start timing of the first integration circuit with respect to the operation start timing of the second integration circuit.
The first integration circuit 93 inputs the reference signal R and outputs the integration value S ₁ . The second integration circuit 94 inputs the second analog amount A ₂ and outputs the integration value S ₂ . The target signal output circuit 95 compares the time until each of the first integration circuit 93 and the second integration circuit 94 reaches a threshold value, and generates a target signal _Stgt .

The target signal output circuit 95 can be configured to operate with a clock that is substantially an integer multiple of the clock clk by performing multiphase processing on the reference clock clk. That is, N clocks clk having the same frequency are generated from the reference clock clk, and these are subjected to delay processing of TP / N, 2TP / N,. By adopting a signal obtained by synthesizing as a new clock, it can be configured to perform high-speed operation.

FIG. 15B shows threshold value TH _R1 , integral value S ₁ , accelerated clock clkR , threshold value TH _A2 , integrated value S ₂ , and accelerated clock clk _A2 .

JP2009-38821A

For example, the signal generation device 9 shown in FIG. 15A is used in the control circuit of the power conversion device, the signal input to the first integration circuit 93 is the voltage, and the signal input to the second integration circuit 93. Is a current measured simultaneously with a predetermined detection value (voltage or current).
In the signal generating device 9, the delay circuit 92 is provided in the preceding stage of the first integrating circuit 93, so that a time difference occurs between the signals input to the first integrating circuit 93 and the second integrating circuit 94.

For this reason, when the voltage or current changes suddenly, the voltage or current that should be input at the same time is not substantially input at the same time, and the target signal output circuit 95 outputs a highly accurate signal. Cannot output.
Further, when there is a temperature error or a product error in the characteristics of the first integration circuit 93 or the second integration circuit 94, the degree of freedom of correction and calibration between the integration circuits is small.
An object of the present invention is to provide a signal generator using at least two integrating circuits, or using at least one oscillating circuit and at least one integrating circuit, so that each signal is input to the integrating circuit and the oscillating circuit without time difference. Furthermore, it is easy to correct and calibrate the integration circuit and the oscillation circuit.
Another object of the present invention is to increase the resolution of the relative delay time of the output of the integration circuit or the oscillation circuit.

(1)
A signal generator used for a control device of a power conversion circuit,
A plurality of integration circuits that input a plurality of analog signals , each of which is a predetermined detection value of the power conversion circuit, and output integration signals obtained by integrating the analog signals, respectively;
A plurality of comparison circuits that respectively input the plurality of integration signals, compare the magnitude of the integration signal with a predetermined threshold value, and output a comparison signal;
At least one delay circuit that inputs each comparison signal and outputs a delayed signal obtained by delaying all or part of these input signals by a set time;
A signal processing circuit that inputs each delayed signal and a comparison signal that is not delayed by the delay circuit, compares the input timing of these input signals, and outputs a signal according to these input timings;
A signal generator comprising:

(2)
A signal generator used for a control device of a power conversion circuit,
A plurality of integration circuits that input a plurality of analog signals , each of which is a predetermined detection value of the power conversion circuit, and output integration signals obtained by integrating the analog signals, respectively;
At least one delay circuit that inputs the integration signal and outputs a delay signal obtained by delaying all or part of the plurality of integration input signals by a set time;
A plurality of comparison circuits that input each delayed signal and an integration signal that has not been delayed by the delay circuit, compare the magnitude of these inputs with a predetermined threshold value, and output a comparison signal, respectively.
A signal processing circuit that inputs each comparison signal, compares the input timing of each input signal, and outputs a signal according to these input timings;
A signal generator comprising:

( 3 )
At least one integration circuit that inputs at least one analog signal and outputs an integrated signal obtained by integrating the analog signal;
At least one delay circuit that inputs each of the integrated signals and outputs a delayed signal obtained by delaying all or part of the integrated signals by a set time;
A plurality of comparison circuits that input the respective delay signals, compare the magnitudes of these inputs with a predetermined threshold value, and output comparison signals, respectively.
At least one oscillator circuit each generating a pulse signal;
At least one delay circuit that inputs each of the pulse signals and outputs a delayed signal obtained by delaying all or part of the pulse signals by a set time;
A signal processing circuit that inputs each delayed signal and a comparison signal that is not delayed by the delay circuit, compares the input timing of each input signal, and outputs a signal corresponding to the input timing;
A signal generator comprising:

( 4 )
At least one integration circuit that inputs at least one analog signal and outputs an integrated signal obtained by integrating the analog signal;
A plurality of comparison circuits that input the respective integration signals , compare the magnitudes of these inputs with a predetermined threshold value, and output comparison signals, respectively.
At least one delay circuit that inputs each of the comparison signals and outputs a delayed signal obtained by delaying all or part of the comparison signals by a set time;
At least one oscillator circuit each generating a pulse signal;
At least one delay circuit that inputs each of the pulse signals and outputs a delayed signal obtained by delaying all or part of the pulse signals by a set time;
A signal processing circuit that inputs each delayed signal, and a comparison signal and a pulse signal that are not delayed by the delay circuit, compares the input timing of each input signal, and outputs a signal corresponding to the input timing;
A signal generator comprising:

In the signal generator of the present invention, each signal is input to the integrating circuit and the oscillating circuit without a time difference, so that when the present invention is applied to the control circuit of the power converter, highly accurate control is possible. .
In the signal generator of the present invention, the integration circuit and the oscillation circuit can be easily corrected and calibrated.
In the signal generator of the present invention, the resolution of the relative delay time of the output of the integration circuit or the oscillation circuit can be increased.

It is explanatory drawing which shows 1st Embodiment of the signal generator of this invention. It is a figure which shows the structural example of a delay circuit, (A) shows a parallel type delay circuit, (B) has shown the serial type delay circuit. It is operation | movement explanatory drawing of the signal generator of FIG. It is explanatory drawing which shows 2nd Embodiment of the signal generator of this invention. It is explanatory drawing which shows 3rd Embodiment of the signal generator of this invention. It is operation | movement explanatory drawing of the signal generator of FIG. It is explanatory drawing which shows 4th Embodiment of the signal generator of this invention. It is operation | movement explanatory drawing of the signal generator of FIG. It is explanatory drawing which shows 1st Embodiment of the digital signal generation circuit of this invention. FIG. 10 is an operation explanatory diagram of the digital signal generation circuit of FIG. 9. It is explanatory drawing which shows 1st Embodiment of the digital signal generation circuit of this invention. It is operation | movement explanatory drawing of the digital signal generation circuit of FIG. It is explanatory drawing which shows 1st Embodiment of the digital signal generation circuit of this invention. It is operation | movement explanatory drawing of the digital signal generation circuit of FIG. It is explanatory drawing of a prior art, (A) is a block diagram of the conventional signal generator, (B) is operation | movement explanatory drawing of the signal generator of (A).

Embodiments of the present invention will be described below. The signal generator 1 repeats the above operation every predetermined period (not necessarily a constant period), but the integration circuit, the oscillation circuit , the comparison circuit, the delay circuit, etc. are well known for resetting and data clearing. Since it is a matter, explanation is omitted.

1A and 1B are explanatory views showing a first embodiment of the signal generator of the present invention.
In FIG. 1A, the signal generation device 1 includes two integration circuits 111 and 112, two comparison circuits 121 and 122, delay circuits 131 and 132, and a signal processing circuit 14.
The integration circuit 111 receives the reference analog signal A ₁ and integrates it to output an integration signal S _A1 . The integration circuit 112 receives the measurement analog signal A ₂ and integrates it to output an integration signal S _A2 .
Comparison circuit 121 compares integrated value S _A1 with threshold value TH ₁ and outputs comparison signal S _CA1 . Comparison circuit 122 compares integrated value S _A1 with threshold value TH ₂ and outputs comparison signal S _CA2 .

The delay circuits 131 and 132 are configured such that the delay times DT ₁ and DT ₂ are set in a programmable manner. The delay circuit 131 receives the comparison signal S _CA1 and outputs a delay signal S _{D C A1} corresponding to the input timing of the comparison signal S _CA1 . The delay circuit 132 receives the comparison signal S _CA2 and outputs a delay signal S _{D C A2} corresponding to the input timing of the comparison signal S _CA2 .

The signal processing circuit 14 receives the delay signals S _DCA1 and S _DCA2 from the delay circuits 131 and 132, _compares these timings (see t ₁ and t _{2 in} FIG. 3), and compares the comparison result signals according to the timings. SC is output. Here, the signal processing circuit 14 determines the _{preceding and succeeding} delay signals S _DCA1 and S _{DCA2 and outputs} the result as comparison result signals SC (SC ₁ and SC ₂ ).

2A and 2B show configuration examples of the delay circuit 81 (corresponding to the delay circuits 131 and 132 in FIG. 1). FIG. 2A shows a parallel delay circuit, and the delay circuit 81 is composed of a plurality of (here, 10) delay circuit elements e _DLY1 , e _DLY2 ,..., E _DLY10 connected in series. Signals before and after connection and between delay circuit elements are input to the selection circuit 80. A selection signal SLCT is input to the selection circuit 80, and the selection circuit 80 delays the input signal (indicated by the integration signal S _A in FIG. 2A) for a predetermined time in accordance with the selection signal SLCT. In FIG. 2 (A), it is output to the signal processing circuit 14 as a delayed signal _SDA ).

FIG. 2B shows a serial delay circuit, and a group of delay circuit elements e _DLY1 , e _DLY2 ,..., E _DLY10 and a selection circuit 80 in FIG. 2 (B) shows an example in which three stages are connected in series. In the delay circuit 83 of FIG. 2 (B), the group with the first stage of the delay circuit elements consisting of the selecting circuit 80 1 generates a delay of 9Tau _c 0, 2 stage delay circuit elements and the selection circuit 80 2 group consisting generates delays 90Tau _c from 10Tau _c, the group consisting of selecting circuit 80 3 and the delay circuit elements of the third stage, it is possible to generate a delay of 900Tau _c from 100Tau _c, thereby, The entire delay circuit 82 can generate a delay time from 0 to 999τ _c .

FIG. 3 shows the relationship among the integration signals S _A1 and S _A2 , the comparison signals S _CA1 and S _CA2 , the delay signals S _DCA1 and S _DCA2, and the comparison result signals SC ₁ and SC ₂ . As shown in FIG. 3, when the delay signals S _{DCA1 and} S _DCA2 reach the thresholds TH ₁ and TH ₂ (time t ₁ and t ₂ ), the signal processing circuit 14 determines the timing before and after these timings. to decide. In Figure 3, the signal processing circuit 14, the rising edge of the S _DCA1, when entered before the rising edge of the S _DCA2 outputs SC _1, the rising edge of the S _DCA1 the rising edge of the S _DCA2 conversely when it was also previously input to output the SC _2.

Note that the delay circuits 131 and 132 may be provided immediately after the integration circuits 111 and 112, and the comparison circuits 121 and 122 may be provided at the subsequent stages. In this case, the integration signals S _A1 and S _A2 themselves are delayed by the delay circuits 131 and 132, and the signal processing circuit 134 determines the preceding and succeeding comparison signals output from the comparison circuits 121 and 122, and compares the result with the comparison result. The signal SC (SC ₁ or SC ₂ ) is output.

4 (A) and 4 (B) are explanatory views showing a second embodiment of the signal generator of the present invention.
4A, the signal generator 2 includes two oscillation circuits 211 and 212, two delay circuits 231 and 232, and a signal processing circuit 24.
The oscillation circuit 211 receives the reference set value SET _REF1 and outputs a pulse S _PLS1 . The oscillation circuit 212 receives the reference set value SET _REF2 and outputs a pulse S _PLS2 .

The delay circuits 231 and 232 are configured such that the delay times DT ₁ and DT ₂ are set in a programmable manner. The delay circuit 231 receives the pulse S _PLS1 and outputs a delay signal S _DPLS1 corresponding to the input timing of the pulse S _PLS1 . The delay circuit 232 receives the pulse S _PLS2 and outputs a delay signal S _DPLS2 corresponding to the input timing of the pulse S _PLS2 .

The signal processing circuit 24 receives the delay signals S _DPLS1 and S _DPLS2 from the delay circuits 231 and 232, compares the timing of the rising edge (or falling edge), and outputs the comparison result signal SC corresponding to the timing. . Here, the signal comparison circuit 24 determines whether the delay signals S _DPLS1 and S _{DPLS2 precede} and _follow , and _outputs the result as comparison result signals SC (SC ₁ and SC ₂ ). The signal processing circuit 24, for example, the delay signal S edges _DPLS1 outputs the SC ₁ as early than the edge of the delayed signal S _DPLS2, as early than the edge of the edge delay signal S _DPLS1 delayed signal S _DPLS2 SC ₂ Is output.

4B, the signal generator 2 includes three oscillation circuits 211, 212, and 213, two delay circuits 231 and 232, and a signal processing circuit 24. FIG. 4B shows a configuration in which an oscillation circuit 213 is added to FIG. 4A, and the oscillation circuit 213 inputs a reference set value SET _REF3 and outputs a pulse S _PLS3 . Although a delay circuit is provided at the subsequent stage of the oscillation circuits 211 and 212, no delay circuit is provided at the subsequent stage of the oscillation circuit 213.

The signal processing circuit 24, compares the timing of the delay signal from the delay circuit 231,232 S _DPLS1, S _DPLS2 and receives a signal S _PLSPLS3 undelayed from the oscillation circuit 213, the rising edge (or falling edge) Then, the comparison result signal SC corresponding to the timing is output. Here, the signal comparison circuit 24 determines the _preceding and _succeeding signals S _DPLS1 , S _DPLS2 , S _{PLS3 and outputs} the result as a comparison result signal SC (SC ₁ , SC ₂ , SC ₃ ).
The signal processing circuit 24, for example, among the delayed signals _{S DPLS1, S DPLS2, S PLS3} , outputs SC ₁ as early as the edges of S _DPLS1 the most, and outputs the SC ₂ as early edge S _DPLS2 the most , and it outputs the SC ₃ as early as the edge of S _PLS3 is the best.

FIGS. 5A and 5B are explanatory views showing a third embodiment of the signal generator of the present invention.
In FIG. 5A, the signal generator 3 includes an oscillation circuit 311, an integration circuit 312, a comparison circuit 321, delay circuits 331 and 332, and a signal processing circuit 34.
The oscillation circuit 311 outputs a pulse S _PLS having a period T _REF based on the reference set value SET _REF . The integration circuit 312 receives the measurement analog signal A, integrates it, and outputs an integration signal S _A. The comparison circuit 321 receives the integration signal S _A , compares it with the threshold value TH, and outputs a comparison signal S _CA.

The delay circuits 331 and 332 are configured such that the delay times DT ₁ and DT ₂ are set in a programmable manner. Delay circuits 331 and 332 receives a pulse S _PLS and the comparison signal S _CA, the delay signal S _DPLS in response to those input timing, and outputs a S _{D C A.}

The signal processing circuit 34 receives the delay signals S _DPLS and S _DCA from the delay circuits 331 and 332, compares the input timings, and outputs a comparison result signal SC corresponding to the timings. Here, the signal processing circuit 34 determines the front-rear of the delayed signal S _DPLS, S _{D C A,} and outputs the compared result result signal _{SC (SC 1, SC 2)} .
As the delay circuits 331 and 332, a circuit having the same configuration as that of the delay circuits 81 and 82 shown in FIGS. 2A and 2B can be used.

FIG. 6 shows the relationship between the delay signals S _DPLS and S _DCA and the comparison result signals SC ₁ and SC ₂ . As shown in FIG. 6, it is _{determined whether} the delay signal S _DPLS falls (time t ₁ ) and the delay signal S _DCA falls _earlier (time t ₂ ).

5B, the signal generator 3 includes three oscillation circuits 311 , 312, and 313 , two integration circuits 314 and 315, two comparison circuits 324 and 325 , and three delay circuits 331, 332, and the like. 334 and a signal processing circuit 34.
Oscillator circuit 311, 312 and 313, based on the reference set value _{SET REF1, SE T REF2, SET} REF3, and outputs a pulse S _PLS1, S _PLS2, S _PLS3 period _{T REF1, T REF2, T REF3} .
The integration circuits 314 and 315 receive the measurement analog signals A ₁ and A ₂ , integrate them and output the integration signals S _A1 and S _A2 , respectively. The comparison circuits 324 and 325 output the integration signals S _{A1 and} S _A2 . type, these thresholds TH _1, TH ₂ and compared, and outputs a comparison signal S _CA1, S _CA2.

The delay circuits 331, 332, and 334 are configured such that the delay times DT ₁ , DT ₂ , and DT ₃ are set in a programmable manner. The delay circuits 331 and 332 _receive the pulses S _PLS1 and S _PLS2 and output delay signals S _DPLS1 and S _DPLS1 corresponding to the input timings. The delay circuit 334 receives the comparison signal S _CA1 and outputs a delay signal S _DCA1 corresponding to these input timings.

The signal processing circuit 34 includes delay signals S _DPLS1 and S _{DPLS 2} from the delay circuits 331 and 332, a pulse S _PLS3 from the oscillation circuit 313 , a delay signal S _DCA1 from the delay circuit 334, and a comparison signal S _CA1 from the comparison circuit 324. Is input, the preceding and following of these input signals are determined, and the result is output as a comparison result signal SC (SC ₁ to SC ₅ ). Signal processing circuit 34, for example, the SC ₁ when you enter the edges of the delayed signal S _DPLS1 of the input signal to the rank, the SC ₂ when you enter the edge of the delayed signal S _DPLS2 to rank When the edge of the pulse S _PLS3 is input first, SC ₃ is input. When the edge of the delay signal S _DCA1 is input first, SC ₄ is input. When the comparison signal S _CA2 is input first. Outputs SC ₅

Note that in FIG. 5B, the delay circuit 334 can be provided immediately after the integration circuit 314. In this case, the integration signal S _A1 itself is delayed by the delay circuit 334, and the signal processing circuit 34 _precedes the delay signal S _DPLS1 , the delay signal S _DPLS2 , the pulse S _PLS3 , the delay signal S _DCA1 , and the comparison signal S _CA2 . Judgment is made, and this result is output as a comparison result signal SC (any one of SC _{1 to} SC ₅ ).

FIG. 7 is an explanatory view showing a fourth embodiment of the signal generator of the present invention.
In FIG. 7, the signal generation device 4 includes an oscillation circuit 40, two integration circuits 411 and 412, comparison circuits 421 and 422, delay circuits 431 and 432, and a signal processing circuit 44.
The oscillation circuit 40 outputs a pulse S _PLS having a period T _REF based on the reference set value SET _REF . The pulse S _PLS is input to the delay circuit 431. The delay circuit 431 is configured such that the delay time DT ₁ is set to the pulse S _PLS in a programmable manner. The delay circuit 431 receives the pulse S _PLS and outputs a delay signal S _DPLS corresponding to the input timing of the pulse S _PLS . The delay signal S _DPLS is input to the integration circuit 411. The integration circuit 411 outputs the integration signal S _ADPLS to the comparison circuit 421, and the comparison circuit 421 outputs the comparison signal S _CADPLS .

On the other hand, the integration circuit 412 receives the measurement analog signal A, integrates it and outputs the integration signal S _A to the comparison circuit 422, and the comparison circuit 422 outputs the comparison signal S _CA. The delay circuit 432 is configured such that the delay time DT ₂ is set in a programmable manner. The delay circuit 432 receives the comparison signal S _CA and outputs a delay signal S _DCA corresponding to the input timing of the comparison signal S _CA.

The signal processing circuit 44 receives the comparison signal S _CADPLS from the comparison circuit 421 and the delay signal S _DCA from the delay circuit 432, compares these input timings, and outputs a comparison result signal SC. Here, the signal processing circuit 44 determines whether the comparison signal S _CADPLS and the delay signal S _DCA are ahead of time, and outputs the result as comparison result signals SC (SC ₁ , SC ₂ ).
As the delay circuits 431 and 432, circuits having the same configuration as the delay circuits 81 and 82 shown in FIGS. 2A and 2B can be used.

FIG. 8 shows the relationship between the comparison signal S _CADPLS and the delay signal S _DCA and the comparison result signals SC ₁ and SC ₂ .

FIG. 9 is an explanatory diagram showing a fifth embodiment of the signal generator of the present invention. In FIG. 9, the signal generator 5 includes two integration circuits 511 and 512, two comparison circuits 521 and 522, delay circuits 531 and 532, and a signal processing circuit 54.
Integration circuits 511 and 512, comparison circuits 521 and 522, and delay circuits 531 and 532 are the same as integration circuits 111 and 112, comparison circuits 121 and 122, and delay circuits 131 and 132 of signal generator 1 in FIG. is there.
The signal processing circuit 54 includes two counters 541 and 542 and a digital subtractor 543.

The counters 541 and 542 start counting in _response to the input of a timing edge representing the reference time, and output the count values n ₁ and n ₂ at the edge times of the delay signals S _DCA1 and S _DCA2 , respectively.
Digital differentiator 543, the count value n ₁ and calculates the count value n ₂ the difference, and outputs the operation result as a digital value DV. In the present embodiment, the digital differentiator 543, n ₂ - a n ₁ computed, t ₂ - outputs time as a digital value DV corresponding to t _1.
The sign of the difference between the value n ₁ and the count value n ₂ can be negative , or when performing n ₂ −n ₁ (ie, t ₂ −t ₂ ) as in the present embodiment. sets the offset value to n _2, it is also to n ₂ -n ₁ is always positive. Also, the terminal for outputting the difference value can be changed depending on the magnitude of the count values n ₁ and n ₂ . A circuit that performs such an operation can be easily assumed by those skilled in the art and will not be described further.

As the delay circuits 531, 532, circuits having the same configuration as the delay circuits 81, 82 shown in FIGS. 2A and 2B can be used.
FIG. 10 shows the relationship _among the integration signals S _A1 and S _A2 , the comparison signals S _CA1 and S _CA2 , the delay signals S _DCA1 and S _DCA2, and the digital value DV.

FIG. 11 is an explanatory diagram showing a sixth embodiment of the signal generator of the present invention. In FIG. 11, the signal generator 6 includes an oscillation circuit 611, an integration circuit 612, a comparison circuit 622, delay circuits 631 and 632, and a signal processing circuit 64.
The oscillation circuit 611, the integration circuit 612, the comparison circuit 622, and the delay circuit 632 are the same as the oscillation circuit 311 , the integration circuit 312 , the comparison circuit 321, and the delay circuits 331 and 332 of the signal generator 3 in FIG.
The signal processing circuit 64 includes two counters 641 and 642 and a digital subtractor 643.

The counters 641 and 642 start counting in _response to the input of a timing edge indicating the reference time, and output the count values n ₁ and n ₂ at the edge times of the delay signals S _DPLS and S _DCA , respectively.
Other operation of the counter 641 and the digital differentiator 643 is basically to be the same as the operation of the counter 541 and the digital differentiator 543 shown in FIG.

As the delay circuits 631 and 632, a circuit having the same configuration as the delay circuits 81 and 82 shown in FIGS. 2A and 2B can be used.
FIG. 12 shows the relationship among the integration signal S _A , the comparison signal S _CA , the delay signals S _{DPLS and} S _DCA , the clock clk, and the digital value DV.

FIG. 13 is an explanatory diagram showing a seventh embodiment of the digital signal generating circuit of the present invention. In FIG. 13, the signal generator 7 includes an oscillation circuit 70, two integration circuits 711 and 712, two comparison circuits 721 and 722, two delay circuits 731 and 732, and a signal processing circuit 74. Yes.
The oscillation circuit 70, the integration circuits 711 and 712, the comparison circuits 721 and 722, and the delay circuits 731 and 732 are the oscillation circuit 40, the integration circuits 411 and 412, the comparison circuits 421 and 422, and the delay circuit 431 of the signal generator 4 of FIG. , 432.
The signal processing circuit 74 includes two counters 741 and 742 and a digital differencer 743.

The counters 741 and 742 start counting by inputting a timing edge that means a reference time, and output count values n ₁ and n ₂ at the edge times of the delay signals S _CADPLS and S _DCA , respectively.
Other operation of the counter 741, 742 and the digital differentiator 743 is basically to be the same as the operation of the counter 541 and the digital differentiator 543 shown in FIG.

As the delay circuit 732, a circuit having the same configuration as that of the delay circuits 81 and 82 shown in FIGS. 2A and 2B can be used.
FIG. 14 shows the _{relationship among} the integration signal S _ADPLS , the delay signals S _DPLS, S _DCA , the integration signal S _A , the comparison signal S _CA , the delay signal S _DCA , the clock clk, and the digital value DV.

DESCRIPTION OF SYMBOLS 1 Signal generator 111,112 Integration circuit 121,122 Comparison circuit 131,132 Delay circuit 14 Signal processing circuit

Claims (4)

A signal generator used for a control device of a power conversion circuit,
A plurality of integration circuits that input a plurality of analog signals, which are predetermined detection values of the power conversion circuit, and output integration signals obtained by integrating the analog signals, respectively;
A plurality of comparator circuits said enter each integration signal, and outputs the respective integrated signal magnitude a predetermined compared to threshold comparison signal, respectively,
At least one delay circuit that inputs each comparison signal and outputs a delayed signal obtained by delaying all or part of these input signals by a set time;
A signal processing circuit that inputs each delayed signal and a comparison signal that is not delayed by each delay circuit, compares the input timing of these input signals, and outputs a signal corresponding to these input timings;
A signal generator comprising: A signal generator used for a control device of a power conversion circuit,
A plurality of integration circuits that input a plurality of analog signals, which are predetermined detection values of the power conversion circuit, and output integration signals obtained by integrating the analog signals, respectively;
At least one delay circuit that inputs each of the integration signals and outputs a delayed signal obtained by delaying all or part of these input signals by a set time;
Wherein each delay signal, and the by the respective delay circuits enter the integration signal is not delayed, by comparing the size of these input signals with a predetermined threshold value, a plurality of comparison to output the comparison signal Circuit,
The type of each comparison signal, a signal processing circuit for comparing the input timing of these input signals, and outputs a signal corresponding to these input timing,
A signal generator comprising: At least one integration circuit that inputs at least one analog signal and outputs an integrated signal obtained by integrating the analog signal;
At least one delay circuit that inputs each of the integrated signals and outputs a delayed signal obtained by delaying all or part of the integrated signals by a set time;
A plurality of comparison circuits that input the respective delay signals, compare the magnitudes of these inputs with a predetermined threshold value, and output comparison signals, respectively.
At least one oscillator circuit each generating a pulse signal;
At least one delay circuit that inputs each of the pulse signals and outputs a delayed signal obtained by delaying all or part of the pulse signals by a set time;
A signal processing circuit that inputs each delayed signal and a comparison signal that is not delayed by the delay circuit, compares the input timing of each input signal, and outputs a signal corresponding to the input timing;
A signal generator comprising: At least one integration circuit that inputs at least one analog signal and outputs an integrated signal obtained by integrating the analog signal;
A plurality of comparison circuits that input the respective integration signals, compare the magnitudes of these inputs with a predetermined threshold value, and output comparison signals, respectively.
At least one delay circuit that inputs each of the comparison signals and outputs a delayed signal obtained by delaying all or part of the comparison signals by a set time;
At least one oscillator circuit each generating a pulse signal;
At least one delay circuit that inputs each of the pulse signals and outputs a delayed signal obtained by delaying all or part of the pulse signals by a set time;
A signal processing circuit that inputs each delayed signal, and a comparison signal and a pulse signal that are not delayed by the delay circuit, compares the input timing of each input signal, and outputs a signal corresponding to the input timing;
A signal generator comprising:

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