JP6701685B2 - Duty ratio adjustment circuit - Google Patents

Description

  The present invention relates to a duty ratio adjusting circuit that adjusts a duty ratio of an input signal and outputs the adjusted duty ratio.

  A circuit having a function of adjusting a duty ratio of an input signal and outputting the adjusted duty is known. For example, the level conversion circuit with duty correction disclosed in Patent Document 1 has a CML (Current Mode Logic) differential buffer unit, a level conversion unit, and a duty correction unit. Here, the CML differential buffer unit differentially amplifies the positive-phase input signal and the negative-phase input signal and outputs the positive-phase output signal and the negative-phase output signal. The level conversion unit performs level conversion of the positive phase output signal and the negative phase output signal and outputs the level-converted signal. The duty correction unit includes a positive-phase integrated voltage corresponding to a period during which the level-converted positive-phase output signal maintains the H level and a negative-phase integrated voltage corresponding to a period during which the level-converted negative-phase output signal maintains the H level. To generate an output offset voltage corresponding to the difference between the positive phase integrated voltage and the negative phase integrated voltage in the CML differential buffer section. As a result of performing this negative feedback control, in the level conversion circuit with duty correction disclosed in Patent Document 1, the duty ratio of the output signal of the level conversion unit is maintained at 50%.

JP, 2007-329924, A

  By the way, the CML type differential amplifier circuit such as the CML differential buffer unit used in the technique of Patent Document 1 has a small noise generated from the circuit and has an ability to remove common-mode noise input from the outside. Since it is excellent and can operate at high speed, it is sometimes used for an ultra-high-speed frequency divider circuit or a driver for high-speed signal transmission. In these applications, differential signals with various duty ratios may be transmitted.

  In the example shown in FIG. 7A, the divide-by-2 circuit divides the differential signal composed of the positive-phase input signal INP and the negative-phase input signal INN into two, and the positive-phase output signal OUTP having a frequency of ½. And the reverse-phase output signal OUTN is output. In such a case, the period A of OUTP>OUTN and the period B of OUTP<OUTN are the same regardless of the magnitude of the output amplitude |OUTP-OUTN| The signal duty ratio is 50%.

  On the other hand, in the example shown in FIG. 7B, the divide-by-3 circuit divides the differential signal composed of the positive-phase input signal INP and the negative-phase input signal INN into three, and the frequency is ⅓. The phase output signal OUTP and the reverse phase output signal OUTN are output. In such a case, the following problems occur. First, since the divide-by-three circuit divides the differential signal composed of the positive-phase input signal INP and the negative-phase input signal INN by three, originally, as shown in the upper part of FIG. The positive phase output signal OUTP and the negative phase output signal OUTN in which the ratio of the length of the period A where >OUTN and the length of the period B where OUTP<OUTN are 1:2 should be output from the divide-by-3 circuit. is there. However, as shown in the lower part of FIG. 7B, the balance of the DC level is lost, the output amplitude |OUTP-OUTN| of the period A is small, and conversely, the output amplitude |OUTP-OUTN| of the period B is large and the DC balance is large. That is, the normal phase output signal OUTP and the negative phase output signal OUTN in which the ratio of the lengths of the periods A and B is not 1:2 are output from the differential amplifier circuit at the output stage of the divide-by-3 circuit. This problem remarkably appears when the frequency dividing ratio of the frequency dividing circuit is 3.

Hereinafter, this problem will be described in more detail with reference to FIG.
In the example shown in FIG. 8A, with respect to the positive-phase input signal INP and the negative-phase input signal INN given to the differential amplifier circuit, the differential amplitude |INP-INN| The differential amplitude |INP-INN| in the period B where <INN is substantially equal. In such a case, since there is no large difference between the direct current level (average level) of the positive phase input signal INP and the direct current level of the negative phase input signal INN, distortion of the positive phase input signal INP and the negative phase input signal INN A small number of positive-phase output signals OUTP and negative-phase output signals OUTN are obtained from the differential amplifier circuit.

  However, as illustrated in FIG. 8B, the differential amplitude |INP-INN| in the period A in which INP>INN is greater than the differential amplitude |INP-INN| in the period B in which INP<INN. If it is significantly small, there is a large difference between the DC level (average level) of the positive phase input signal INP and the DC level of the negative phase input signal INN. Therefore, the positive phase output signal OUTP and the negative phase output signal OUTN whose DC levels are greatly separated are obtained from the differential amplifier circuit. Then, in the worst case, as illustrated in FIG. 8B, the positive phase output signal OUTP and the negative phase output signal OUTN that do not cross each other and do not function as a differential signal are obtained from the differential amplifier circuit. This is the problem of loss of differential signals.

  In the example of the frequency dividing circuit described above, the DC signal is lost in the differential signal input to the differential amplifying circuit at the output stage of the frequency dividing circuit by 3, so that an undesired state as shown in the lower stage of FIG. 7B is generated. Appropriate positive-phase output signal OUTP and negative-phase output signal OUTN are output.

  In order to avoid such a problem, means for adjusting the differential signal to be transmitted to an arbitrary duty ratio including a duty ratio other than 50% is required.

  However, the level conversion circuit with duty correction disclosed in Patent Document 1 can only adjust the duty ratio of the output signal to 50%, and cannot be a means for solving the above-mentioned problem.

  The present invention has been made in view of the circumstances described above, and provides a duty ratio adjusting circuit that can adjust and output the duty ratio of an input signal to any duty ratio including a duty ratio other than 50%. The purpose is to do.

  The present invention provides a driver circuit that differentially amplifies a positive-phase input signal and a negative-phase input signal to output a positive-phase output signal and a negative-phase output signal, and a first circuit while the positive-phase output signal is at a first level. An integrating operation unit that integrates the current and outputs the first integrated voltage, and outputs the second integrated voltage by integrating the second current while the negative-phase output signal is at the first level; Duty ratio setting means for switching the first current and the second current according to the duty ratio, and the output of the positive phase output signal with respect to the negative phase output signal according to the difference between the first integrated voltage and the second integrated voltage A duty ratio adjusting circuit, comprising: an offset correcting unit that corrects an offset voltage.

  According to the present invention, the duty ratio setting means switches between the first current and the second current according to the target duty ratio, and by this switching, the integral calculation unit outputs the first integrated voltage that is the integral of the first current. A second integrated voltage, which is the integration of the second current, is output, and the offset correction unit corrects the output offset voltage according to the difference between the first integrated voltage and the second integrated voltage. With this correction, the duty ratios of the positive-phase output signal and the negative-phase output signal output by the driver circuit can be brought close to desired values.

  In a more preferable aspect, the integral calculation unit includes a first capacitor, a first variable resistor, a second capacitor, and a second variable resistor, and the positive-phase output signal is at the first level. During a certain period of time, the first current is charged through the first variable resistor to charge the first capacitor, and while the negative-phase output signal is at the first level, the second current through the second variable resistor is applied. The current is used to charge the second capacitor, and the charging voltage of the first capacitor and the charging voltage of the second capacitor are output as the first integrated voltage and the second integrated voltage. The duty ratio setting means Switches the resistance values of the first variable resistor and the second variable resistor according to the target duty ratio.

  According to this aspect, by switching the resistance values of the first variable resistor and the second variable resistor, it is possible to bring the duty ratios of the positive-phase output signal and the negative-phase output signal close to desired values.

  In a more preferable aspect, the integral correction unit that corrects the first current and the second current according to the duty ratio of the positive phase input signal and the negative phase input signal is provided.

  According to this aspect, the integral correction unit relaxes the excessive correction of the output offset voltage of the offset correction unit. Therefore, it is possible to bring the duty ratios of the positive-phase output signal and the negative-phase output signal closer to desired values.

  In a more preferable aspect, the integral calculation unit includes a first transistor inserted in the path of the first current and a second transistor inserted in the path of the second current, and the integral correction unit Corrects the first current and the second current by controlling the respective gate voltages supplied to the first and second transistors.

  According to this aspect, the duty ratio of the positive-phase output signal and the negative-phase output signal can be brought close to a desired value by the first transistor and the second transistor of the integral calculation unit.

  In a more preferable aspect, the integral correction unit supplies the gate voltage according to the period when the positive-phase input signal is at the second level to the first transistor, and the gate voltage during the period when the negative-phase input signal is at the second level. A corresponding gate voltage is supplied to the second transistor.

  According to this aspect, it is possible to bring the duty ratios of the positive phase output signal and the negative phase output signal close to desired values.

FIG. 3 is a circuit diagram showing a configuration of a duty ratio adjusting circuit 100 that is an embodiment of the present invention. 3 is a time chart showing waveforms of various parts of the duty ratio adjusting circuit 100. A time chart showing the result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjustment circuit 100 and the normal differential amplifier circuit for the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 30%. Is. A time chart showing the result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjustment circuit 100 and the normal differential amplifier circuit for the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 50%. Is. A time chart showing the result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 and the normal differential amplifier circuit for the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 20%. Is. 6 is a graph summarizing simulation results. FIG. 6 is a diagram showing the dependence of the waveforms of the positive-phase output signal OUTP and the negative-phase output signal OUTN on the frequency division ratio in the frequency dividing circuit. It is a figure which shows the dependence with respect to the duty ratio of the waveform of the positive phase output signal OUTP and the negative phase output signal OUTN in a differential amplifier circuit.

  An embodiment of the present invention will be described below with reference to the drawings.

(A: configuration)
FIG. 1 is a circuit diagram showing a configuration of a duty ratio adjusting circuit 100 according to an embodiment of the present invention. The duty ratio adjusting circuit 100 is a circuit that adjusts the duty ratios of the positive-phase input signal INP and the negative-phase input signal INN to a designated target duty ratio, and outputs them as the positive-phase output signal OUTP and the negative-phase output signal OUTN. As shown in FIG. 1, the duty ratio adjustment circuit 100 includes a driver circuit 1, a DC voltage offset correction unit 2, an integration calculation unit 3, and an integration correction unit 4.

  The driver circuit 1 differentially amplifies the positive-phase input signal INP and the negative-phase input signal INN, and outputs the positive-phase output signal OUTP and the negative-phase output signal OUTN. The DC voltage offset correction unit 2 corrects the output offset voltage VOFFSET of the positive phase output signal OUTP with respect to the negative phase output signal OUTN when the positive phase input signal INP and the negative phase input signal INN match in the driver circuit 1. Is. The integration calculator 3 integrates the first current I37 during the period in which the positive-phase output signal OUTP is at the first level (H level in this embodiment), and outputs the integrated value of the first integrated voltage. V37 is output, and the second current I38 is integrated during the period in which the negative-phase output signal OUTN is at the first level (H level in the present embodiment), and the second integrated voltage V38 that is the integrated value thereof. Is a circuit for outputting. The DC voltage offset correction unit 2 described above controls the output offset voltage VOFFSET generated in the driver circuit 1 according to the magnitude relation between the first integrated voltage V37 and the second integrated voltage V38. The integration correction unit 4 corrects the first current I37 and the second current I38 of the integration calculation unit 3 according to the duty ratios of the positive-phase input signal INP and the negative-phase input signal INN.

  The driver circuit 1 is an N-channel MOSFET (Metal Oxide Semiconductor Field Effect Transistor; a metal oxide semiconductor field effect transistor; hereinafter simply referred to as a transistor) 11 and 12, resistors 13 and 14, and a current value I1. It is a differential amplifier including a constant current source 15. Here, the sources of the N-channel transistors 11 and 12 are connected to each other, and the constant current source 15 is interposed between the connection point of the sources and the low-potential power supply VSS. The resistor 13 is inserted between the drain of the N-channel transistor 11 and the high potential power supply VDD, and the resistor 14 is inserted between the drain of the N-channel transistor 12 and the high potential power supply VDD. The positive-phase input signal INP is input to the gate of the N-channel transistor 11, and the negative-phase input signal INN is input to the gate of the N-channel transistor 12. The drain of the N-channel transistor 11 is the output node of the negative phase output signal OUTN, and the drain of the N-channel transistor 12 is the output node of the positive phase output signal OUTP.

  The DC voltage offset correction unit 2 includes N-channel transistors 21 and 22, and a constant current source 23 having a current value I2 that is interposed between a connection point between sources of these transistors and the low potential power supply VSS. ing. Here, the drain of the N-channel transistor 21 is connected to the connection point of the drain of the N-channel transistor 11 of the driver circuit 1 and the resistor 13, and the drain of the N-channel transistor 22 of the N-channel transistor 12 of the driver circuit 1. It is connected to the connection point of the drain and the resistor 14. Further, the gate of the N-channel transistor 22 is supplied with the first integrated voltage V37 from the integration calculation unit 3, and the gate of the N-channel transistor 21 is supplied with the second integration voltage V38 from the integration calculation unit 3.

  The integration calculation unit 3 includes N-channel transistors 31 and 32, P-channel transistors 33 and 34, variable resistors 35 and 36, capacitors 37 and 38, a constant current source 39 having a current value of I3, and a resistance adjustment unit 30. Have and. Here, the sources of the N-channel transistors 31 and 32 are connected to each other, and the constant current source 39 having a current value I3 is interposed between the connection point between the sources and the low-potential power supply VSS. The gate of the N-channel transistor 31 is supplied with the negative-phase output signal OUTN, and the gate of the N-channel transistor 32 is supplied with the positive-phase output signal OUTP. The drain of the N-channel transistor 31 is connected to the drain of the P-channel transistor 33, and the drain of the N-channel transistor 32 is connected to the drain of the P-channel transistor 34. A variable resistor 35 is inserted between the source of the P-channel transistor 33 and the high potential power VDD. The variable resistor 35 is means for adjusting the above-mentioned first current I37. Further, a variable resistor 36 is inserted between the source of the P-channel transistor 34 and the high potential power supply VDD. The variable resistor 36 is means for adjusting the above-mentioned second current I38.

  Here, the gate of the P-channel transistor 33 is supplied with the integration correction voltage V45 from the integration correction unit 4, and the gate of the P-channel transistor 34 is supplied with the integration correction voltage V46 from the integration correction unit 4. Then, a first capacitor 37 for integrating the first current I37 is interposed between the connection point between the drains of the N-channel transistor 31 and the P-channel transistor 33 and the low potential power supply VSS, and the N-channel A second capacitor 38 for integrating the second current I38 is inserted between the connection point between the drains of the transistor 32 and the P-channel transistor 34 and the low potential power supply VSS. As described above, since the N-channel transistor 31 receives the negative-phase output signal OUTN at its gate, the negative-phase output signal OUTN is at the second level (L-level in this embodiment) and the positive-phase output signal OUTP is at the same level. It is turned off during the first level (H level in this embodiment). Therefore, the first capacitor 37 integrates the first current I37 while the positive phase output signal OUTP is at the first level (H level in this embodiment). Further, since the N-channel transistor 32 receives the positive-phase output signal OUTP at its gate, the positive-phase output signal OUTP is at the second level (L level in this embodiment) and the negative-phase output signal OUTN is at the first level. It is turned off while it is at the level (H level in this embodiment). Therefore, the second capacitor 38 integrates the second current I38 while the negative-phase output signal OUTN is at the first level (H level in this embodiment). The charging voltages of the capacitors 37 and 38 are supplied to the DC voltage offset correction unit 2 as the above-mentioned first and second integrated voltages V37 and V38.

  The resistance adjusting unit 30 is means for adjusting the first current I37 and the second current I38 by adjusting the resistance values of the variable resistors 35 and 36. In this embodiment, the duty ratios of the positive phase output signal OUTP and the negative phase output signal OUTN are controlled to a desired duty ratio by adjusting the resistance values of the variable resistors 35 and 36. Specifically, in this embodiment, for example, by simulation, the resistance value R35_1 of the variable resistor 35 and the resistance value R36_1 of the variable resistor 36 for setting the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN to DR1. The resistance value R35_2 of the variable resistor 35 having the duty ratio DR2 and the resistance value R36_2 of the variable resistor 36,..., The resistance value R35_N of the variable resistor 35 and the resistance value R36_N of the variable resistor 36 having the duty ratio DRN, and so on. There is a demand for a set of resistance values of each variable resistor for realizing a desired duty ratio. The variable resistor 35 can be switched to a desired one of the resistance values R35_1, R35_2,..., R35_N, and the variable resistor 36 can be switched to a desired one of the resistance values R36_1, R36_2,..., R36_N. It is possible. The resistance adjusting unit 30 receives a duty ratio designating signal designating a target duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN from the outside, and changes the resistance value to a resistance value corresponding to the target duty ratio indicated by the duty ratio designating signal. The resistance values of the resistors 35 and 36 are switched.

The integration correction unit 4 has P-channel transistors 41 and 42, resistors 43 and 44, capacitors 45 and 46, and a constant current source 47 having a current value I4. The sources of the P-channel transistors 41 and 42 are connected to each other, and the constant current source 47 is interposed between the connection point between the sources and the high-potential power supply VDD. The positive phase input signal INP is applied to the gate of the P channel transistor 41, and the negative phase input signal INN is applied to the gate of the P channel transistor 42. A resistor 43 and a capacitor 45 are inserted in parallel between the drain of the P-channel transistor 41 and the low potential power supply VSS, and a resistor 44 and a capacitor are interposed between the drain of the P-channel transistor 42 and the low potential power supply VSS. 46 are inserted in parallel. The respective charging voltages of these capacitors 45 and 46 are supplied to the integral calculating section 3 as the above-mentioned integral correction voltages V45 and V46.
The above is the configuration of the duty ratio adjusting circuit 100.

(B: operation)
Next, the operation of the duty ratio adjusting circuit 100 will be described. In the following, for simplification, it is assumed that the N-channel transistors 11 and 12 have the same electrical characteristics and the N-channel transistors 21 and 22 have the same electrical characteristics. FIG. 2 is a time chart showing the waveform of each part of the duty ratio adjusting circuit 100. FIG. 2A shows waveforms of the positive-phase input signal INP and the negative-phase input signal INN having a duty ratio of 50%, and FIGS. 2B to 2D show N of the DC voltage offset correction unit 2. The figure shows how the waveforms of the positive-phase output signal OUTP and the negative-phase output signal OUTN change when the drain currents I21 and I22 of the channel transistors 21 and 22 are variously changed.

  When the first integrated voltage V37 and the second integrated voltage V38 are equal, the current flows from the drain of the N-channel transistor 11 of the driver circuit 1 and the connection point of the resistor 13 to the drain of the N-channel transistor 21 of the DC voltage offset correction unit 2. The current I21 is equal to the current I22 flowing from the connection point of the drain of the N-channel transistor 12 of the driver circuit 1 and the resistor 14 to the drain of the N-channel transistor 22 of the DC voltage offset correction unit 2. In this case, in the driver circuit 1, the output offset voltage VOFFSET of the positive-phase output signal OUTP with respect to the negative-phase output signal OUTN becomes 0, and as shown in FIG. 2B, the positive-phase input signal INP and the negative-phase input signal INN In response to crossing each other, the positive phase output signal OUTP and the negative phase output signal OUTN cross each other. Therefore, when the duty ratio of the positive phase input signal INP and the negative phase input signal INN is 50%, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN is 50%.

  On the other hand, in the state where the first integrated voltage V37 is higher than the second integrated voltage V38, the current I22 is higher than the current I21. In this case, in the driver circuit 1, the output offset voltage VOFFSET of the positive phase output signal OUTP with respect to the negative phase output signal OUTN has a negative voltage value, and the positive phase input signal INP is the first voltage as shown in FIG. 2C. The positive-phase output signal OUTP is at the first level (the present embodiment) more than the period in which the level (the H-level in the present embodiment) and the negative-phase input signal INN is the second level (the L-level in the present embodiment). , H level), and the period in which the negative-phase output signal OUTN is at the second level (L level in this embodiment) becomes shorter. Further, the positive phase output signal INP is at the second level (L level in the present embodiment), and the positive phase output signal INN is at the first level (H level in the present embodiment) rather than the normal phase output. The period in which the signal OUTP is at the second level (L level in this embodiment) and the anti-phase output signal OUTN is at the first level (H level in this embodiment) becomes longer. In this way, when the first integrated voltage V37 is larger than the second integrated voltage V38, the DC voltage offset correction unit 2 changes the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN to the positive phase input signal INP. , The control is performed such that the duty ratio of the negative-phase input signal INN is smaller than that.

Further, when the first integrated voltage V37 is smaller than the second integrated voltage V38, the current I21 becomes larger than the current I22. In this case, in the driver circuit 1, the output offset voltage VOFFSET of the positive phase output signal OUTP with respect to the negative phase output signal OUTN has a positive voltage value, and as shown in FIG. 2D, the positive phase input signal INP has the first value. The positive phase output signal OUTP is at the first level (this embodiment) compared to the period in which the level (H level in this embodiment) and the negative phase input signal INN is the second level (L level in this embodiment). , H level) and the negative-phase output signal OUTN are at the second level (L level in this embodiment) for a longer period. In addition, the positive phase output signal INP is at the second level (L level in the present embodiment) and the positive phase output is higher than the period in which the negative phase input signal INN is at the first level (H level in the present embodiment). The period in which the signal OUTP is at the second level (L level in this embodiment) and the anti-phase output signal OUTN is at the first level (H level in this embodiment) becomes shorter. In this way, when the first integrated voltage V37 is smaller than the second integrated voltage V38, the DC voltage offset correction unit 2 changes the duty ratios of the positive phase output signal OUTP and the negative phase output signal OUTN to the positive phase input signal INP. , The control is performed such that the duty ratio of the negative-phase input signal INN is made larger.
The above is the control of the duty ratio of the driver circuit 1 performed by the DC voltage offset correction unit 2.

  Next, with reference to FIGS. 2C and 2C1 to 2C5, the relationship between the integration operation of the integration calculation unit 3 and the control of the duty ratio of the driver circuit 1 by the DC voltage offset correction unit 2 will be described. In the example shown in FIG. 2C1, the resistance value of the variable resistor 35 is smaller than the resistance value of the variable resistor 36, and the current I35 flowing through the variable resistor 35 is larger than the current I36 flowing through the variable resistor 36. In the example shown in FIG. 2(c2), as shown in FIG. 2(c), the positive-phase output signal OUTP and the negative-phase output signal OUTN whose duty ratio is smaller than 50% are output, and the integral calculation unit 3 outputs The negative-phase output signal OUTN and the positive-phase output signal OUTP are applied to the gates of the N-channel transistors 31 and 32, respectively. Then, as shown in FIG. 2C3, during the period of OUTP>OUTN, the first current I37=I35 is integrated by the first capacitor 37, and during the period of OUTP<OUTN, the second current I37=I35 is integrated. The integration of I38=I36 is performed by the second capacitor 38. Here, the time constants of the capacitors 37 and 38 and the resistors (for example, the variable resistors 35 and 36) connected to these capacitors are sufficiently large. Therefore, the first integrated voltage V37, which is the charging voltage of the first capacitor 37, is a direct current proportional to the product of the time density (that is, the duty ratio) of the period OUTP>OUTN and the first current I37=I35. It becomes a voltage. Further, the second integrated voltage V38, which is the charging voltage of the second capacitor 38, is proportional to the product of the time density (that is, 1-duty ratio) and the second current I38=I36 in the period of OUTP<OUTN. It becomes a DC voltage. In the example shown in FIG. 2C4, the first integrated voltage V37 is higher than the second integrated voltage V38. Therefore, as shown in FIG. 2C5, in the DC voltage offset correction unit 2, the drain current I22 of the N-channel transistor 22 becomes larger than the drain current I21 of the N-channel transistor 21.

  When the drain current I22 of the N-channel transistor 22 is larger than the drain current I21 of the N-channel transistor 21, as already described, the duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN of the driver circuit 1 are higher than those of the current state. Control to reduce the size is performed. By this control, when the period of OUTP>OUTN becomes short and the period of OUTP<OUTN becomes long, the first integrated voltage V37 decreases and the second integrated voltage V38 increases.

  As a result of repeating such control, the difference between the first integrated voltage V37 and the second integrated voltage V38 becomes gradually smaller, and the duty ratio of the positive-phase output signal OUTP and the negative-phase output signal OUTN of the driver circuit 1 becomes It converges to a value depending on the ratio of the first current I37=I35 and the second current I38=I36. Specifically, as the first current I37 is increased and the second current I38 is decreased, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN can be decreased.

  The operation in the case where the first current I37 is larger than the second current I38 and the duty ratios of the positive phase output signal OUTP and the negative phase output signal OUTN are adjusted to 50% or less has been described above as an example. The operation when the first current I37 is smaller than the second current I38 and the duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN are adjusted to 50% or more (see FIG. 2D) It is the same. In this case, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN can be increased as the first current I37 is decreased and the second current I38 is increased.

  By the way, when the target duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN is smaller than 50%, and the duty ratio of the positive phase input signal INP and the negative phase input signal INN is also smaller than 50%, If the duty ratio is corrected in the same manner as when the duty ratio of the positive-phase input signal INP and the negative-phase input signal INN is 50%, the correction becomes excessive. Also, in the case where the target duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN is larger than 50%, and the duty ratio of the positive phase input signal INP and the negative phase input signal INN is also larger than 50%. If the same duty ratio correction as in the case where the duty ratios of the positive-phase input signal INP and the negative-phase input signal INN are 50% is performed, the correction becomes excessive. Therefore, in order to mitigate such an excessive duty ratio correction, the integral correction unit 4 adjusts the first current I37 and the first current I37 of the integral calculation unit 3 according to the duty ratios of the positive-phase input signal INP and the negative-phase input signal INN. The current I38 of 2 is corrected.

  More specifically, in the integral correction section 4, the P-channel transistor 41 is turned on during the period when the positive-phase input signal INP is at the second level (L level in this example), and the capacitor 45 causes the current I4 of the constant current source 47 to be changed. Is integrated. Further, in the integration correction unit 4, the P-channel transistor 42 is turned on during the period when the negative-phase input signal INN is at the second level (L level in this example), and the capacitor 46 integrates the current I4 of the constant current source 47. Done. Here, the time constants of the capacitors 45 and 46 and the resistors (for example, the resistors 43 and 44) connected to these capacitors are sufficiently large. Therefore, the integrated correction voltage V45, which is the charging voltage of the capacitor 45, is a DC voltage proportional to the time density (that is, 1-duty ratio) during the period in which the positive-phase input signal INP is at the second level. Further, the integrated correction voltage V46, which is the charging voltage of the capacitor 46, is a DC voltage proportional to the time density (that is, the duty ratio) during the period in which the negative-phase input signal INN is at the second level.

  When the duty ratio of the positive phase input signal INP and the negative phase input signal INN is smaller than 50%, the integral correction voltage V45 becomes higher than the integral correction voltage V46. In this case, in the integral calculation unit 3, the ON resistance of the P-channel transistor 33 becomes higher than the ON resistance of the P-channel transistor 34. As a result, the first current I37 is suppressed more than the second current I38, and excessive correction for reducing the duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN is prevented. ..

  When the duty ratio of the positive-phase input signal INP and the negative-phase input signal INN is larger than 50%, the integral correction voltage V46 becomes higher than the integral correction voltage V45. In this case, in the integral calculation unit 3, the ON resistance of the P-channel transistor 34 becomes higher than the ON resistance of the P-channel transistor 33. As a result, the second current I38 is more suppressed than the first current I37, and excessive correction for increasing the duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN is prevented. ..

  As described above, the duty ratio adjusting circuit 100 according to the present embodiment can adjust the duty ratios of the positive phase output signal OUTP and the negative phase output signal OUTN to any target duty ratios other than 50%.

(C: Simulation)
The applicant confirmed the effect of the duty ratio adjusting circuit 100 by simulation. The operation of the duty ratio adjusting circuit 100 in which the duty ratios of the positive phase output signal OUTP and the negative phase output signal OUTN are specified to be 30%, and the operation from the duty ratio adjusting circuit 100 to the DC voltage offset correction unit 2, the integration calculation unit 3, and the The operation of a circuit from which the integral correction unit 4 is removed (hereinafter referred to as a normal differential amplifier circuit) was compared by a simulation with a frequency of 10 GHz. In this simulation, rectangular waves were used as the positive-phase input signal INP and the negative-phase input signal INN.

  FIG. 3 is a result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 and the normal differential amplifier circuit with respect to the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 30%. 2 is a time chart showing. 3A shows the waveforms of the positive-phase input signal INP and the negative-phase input signal INN, and FIG. 3B shows the normal-phase output signal OUTP and the negative-phase output signal OUTN of the duty ratio adjusting circuit 100. FIG. 3C shows the waveforms of the normal phase output signal OUTP and the reverse phase output signal OUTN of the normal differential amplifier circuit. The target duty ratio of the duty ratio adjusting circuit 100 is 30%. As shown in FIG. 3B, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 was 30%. Further, as shown in FIG. 3C, the duty ratio of the normal phase output signal OUTP and the reverse phase output signal OUTN of the normal differential amplifier circuit was 29.2%. Thus, there is no significant difference in the duty ratio between the duty ratio adjusting circuit 100 and the normal differential amplifier circuit.

  FIG. 4 is a result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 and the normal differential amplifier circuit with respect to the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 50%. 2 is a time chart showing. 4A shows the waveforms of the positive-phase input signal INP and the negative-phase input signal INN, and FIG. 4B shows the normal-phase output signal OUTP and the negative-phase output signal OUTN of the duty ratio adjusting circuit 100. FIG. 4C shows the waveforms of the normal phase output signal OUTP and the reverse phase output signal OUTN of the normal differential amplifier circuit. The target duty ratio of the duty ratio adjusting circuit 100 is 30%. As shown in FIG. 4B, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 was 35.6%. Further, as shown in FIG. 3C, the duty ratio of the normal phase output signal OUTP and the reverse phase output signal OUTN of the normal differential amplifier circuit was 50%. Thus, there is a large difference in the duty ratio between the duty ratio adjusting circuit 100 and the normal differential amplifier circuit. The duty ratios of the normal phase output signal OUTP and the normal phase input signal OUTN of the normal differential amplifier circuit are substantially the same as the duty ratios of the normal phase input signal INP and the negative phase input signal INN. The duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN of the duty ratio adjusting circuit 100 substantially match the target duty ratio.

  FIG. 5 is a result of simulating the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 and the normal differential amplifier circuit with respect to the positive phase input signal INP and the negative phase input signal INN having the duty ratio of 20%. 2 is a time chart showing. 5A shows the waveforms of the positive-phase input signal INP and the negative-phase input signal INN, and FIG. 5B shows the normal-phase output signal OUTP and the negative-phase output signal OUTN of the duty ratio adjusting circuit 100. FIG. 5C shows waveforms of the normal phase output signal OUTP and the reverse phase output signal OUTN of the normal differential amplifier circuit. The target duty ratio of the duty ratio adjusting circuit 100 is 30%. As shown in FIG. 5B, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN of the duty ratio adjusting circuit 100 was 26.3%. Further, as shown in FIG. 5C, the duty ratio of the normal phase output signal OUTP and the negative phase output signal OUTN of the normal differential amplifier circuit was 17.5%. Thus, there is a large difference in the duty ratio between the duty ratio adjusting circuit 100 and the normal differential amplifier circuit. The duty ratios of the normal phase output signal OUTP and the normal phase input signal OUTN of the normal differential amplifier circuit are substantially the same as the duty ratios of the normal phase input signal INP and the negative phase input signal INN. The duty ratios of the positive-phase output signal OUTP and the negative-phase output signal OUTN of the duty ratio adjusting circuit 100 substantially match the target duty ratio.

  FIG. 6 is a graph summarizing the above simulation results. The horizontal axis of FIG. 6 is the input duty ratio showing the duty ratio of the positive phase input signal INP and the negative phase input signal INN, and the vertical axis is the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN. Output duty ratio. As shown in FIG. 6, in the normal differential amplifier circuit, when the input duty ratio is changed to various values, the output duty ratio also changes. On the other hand, in the duty ratio adjusting circuit, the output duty ratio becomes the target duty ratio even if the input duty ratio is changed to various values. As described above, in the duty ratio adjusting circuit 100 according to the present embodiment, the duty ratio of the positive phase output signal OUTP and the negative phase output signal OUTN is set to 50 regardless of the duty ratio of the positive phase input signal INP and the negative phase input signal INN. It can be adjusted to an arbitrary target duty ratio including values other than %.

Although one embodiment of the present invention has been described above, other embodiments can be considered in addition to this. For example:
(1) In the above embodiment, the sources of the N-channel transistors 31 and 32 in the integral calculation unit 3 are connected to the common constant current source, but they may be connected to separate constant current sources.
(2) In the above embodiment, the sources of the P-channel transistors 41 and 42 in the integral correction unit 4 are connected to the common constant current source, but they may be connected to separate constant current sources.
(3) The P-channel transistor in the above embodiment may be an N-channel transistor, the N-channel transistor may be a P-channel transistor, and the high potential power supply VDD and the low potential power supply VSS may be replaced with each other.
(4) In the above embodiment, the MOSFET is used as the transistor, but a bipolar transistor may be used.

1... Driver circuit, 2... DC voltage offset correction unit, 3... Integral calculation unit, 4... Integral correction unit, 11, 12, 21, 22, 31, 32... N-channel transistor, 13, 14, 43, 44... Resistance, 15, 23, 39, 47... Constant current power supply, 30... Resistance adjusting section, 35, 36... Variable resistance, 33, 34, 41, 42... P-channel transistor, 37, 38, 45, 46... Capacitor, 100... Duty ratio adjusting circuit.

Claims (4)

A driver circuit that differentially amplifies a positive-phase input signal and a negative-phase input signal to output a positive-phase output signal and a negative-phase output signal,
An integration calculation unit comprising a first capacitor, a first variable resistor, a second capacitor, and a second variable resistor, wherein the positive phase output signal is at a first level. The first current is charged through the first variable resistor to charge the first capacitor, and the second capacitor is charged through the second variable resistor while the negative-phase output signal is at the first level. An integration calculation unit that causes the second capacitor to be charged by a current and outputs the charging voltage of the first capacitor and the charging voltage of the second capacitor as a first integrated voltage and a second integrated voltage;
Duty ratio setting means for adjusting the ratio of the first current and the second current by adjusting the ratio of the resistance values of the first variable resistor and the second variable resistor according to the target duty ratio. When,
An offset correction unit that corrects an output offset voltage of the positive-phase output signal with respect to the negative-phase output signal according to a difference between the first integrated voltage and the second integrated voltage. Ratio adjustment circuit. The duty ratio according to claim 1, further comprising an integral correction unit that corrects the first current and the second current according to a duty ratio of the positive-phase input signal and the negative-phase input signal. Adjustment circuit. The integration calculation unit includes a first transistor inserted in the first current path and a second transistor inserted in the second current path,
The said integral correction|amendment part correct|amends the said 1st electric current and the said 2nd electric current by controlling each gate voltage supplied to the said 1st and 2nd transistor, The said 2nd characterized by the above-mentioned. Duty ratio adjustment circuit. The integration corrector supplies the first transistor with a gate voltage corresponding to a period in which the positive-phase input signal is at the second level, and supplies a gate voltage to the first transistor in accordance with the period in which the negative-phase input signal is at the second level. The duty ratio adjusting circuit according to claim 3, wherein the gate voltage is supplied to the second transistor.

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