SIGNAL PROCESSING CIRCUIT AND A/D CONVERTER

Information

  • Patent Application
  • 20150213905
  • Publication Number
    20150213905
  • Date Filed
    January 22, 2015
    9 years ago
  • Date Published
    July 30, 2015
    8 years ago
Abstract
A signal processing circuit according to one embodiment includes a rectifier, a holder, a controller, and a setter. The rectifier generates a rectified voltage by rectifying an input voltage in which a signal voltage is superimposed on a common-mode voltage. The holder holds a voltage. The controller controls the holder so that the holder holds a voltage according to the rectified voltage generated by the rectifier. The setter sets the voltage held by the holder to a predetermined voltage at predetermined time intervals.
Description
CROSS REFERENCE TO RELATED APPLICATION(S)

This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2014-014414, filed on Jan. 29, 2014, the entire contents of which are incorporated herein by reference.


FIELD

Embodiments described herein relate generally to a signal processing circuit and an A/D converter.


BACKGROUND

A pipeline A/D converter is employed in a number of LSI products as an architecture which can achieve both high speed and high resolution. The pipeline A/D converter is configured by connecting a plurality of stages for performing A/D conversion of one bit. A sampled analog signal is A/D converted bit by bit in each stage by pipeline operation. Traditionally, an operational amplifier has been used to perform A/D conversion in each stage.


Recently, a technique has been proposed which reduces power consumption of the pipeline A/D converter by using a comparator instead of the operational amplifier in each stage. However, in the above traditional technique using the comparator, since it has been necessary to charge/discharge a capacitive element with every A/D conversion in a signal processing circuit used for A/D conversion, it has been difficult to reduce enough the power consumption.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a block diagram of a signal processing circuit according to a first embodiment;



FIG. 2 is a circuit diagram of an example of the signal processing circuit according to the first embodiment;



FIG. 3 is a circuit diagram of another example of a controller in FIG. 2;



FIGS. 4A to 4D are explanatory diagrams of operation of the signal processing circuit according to the first embodiment;



FIGS. 5A to 5C are explanatory diagrams of the operation of the signal processing circuit according to the first embodiment;



FIG. 6 is a circuit diagram of an example of a traditional signal processing circuit;



FIGS. 7A and 7B are explanatory diagrams of operation of the traditional signal processing circuit;



FIG. 8 is an explanatory diagram of the operation of the traditional signal processing circuit;



FIG. 9 is a block diagram of another example of the signal processing circuit according to the first embodiment;



FIG. 10 is a block diagram of still another example of the signal processing circuit according to the first embodiment;



FIG. 11 is a circuit diagram of an example of a restorator in FIG. 9;



FIG. 12 is a block diagram of yet another of the signal processing circuit according to the first embodiment;



FIG. 13 is a block diagram of a signal processing circuit according to a second embodiment;



FIG. 14 is a circuit diagram of an example of the signal processing circuit according to the second embodiment;



FIG. 15 is a circuit diagram of another example of the signal processing circuit according to the second embodiment; and



FIG. 16 is a circuit diagram of an example of a signal processing circuit according to a third embodiment.





DETAILED DESCRIPTION

Embodiments will now be explained with reference to the accompanying drawings. The present invention is not limited to the embodiments.


A signal processing circuit according to one embodiment includes a rectifier, a holder, a controller, and a setter. The rectifier generates a rectified voltage by rectifying an input voltage in which a signal voltage is superimposed on a common-mode voltage. The holder holds a voltage. The controller controls the holder so that the holder holds a voltage according to the rectified voltage generated by the rectifier. The setter sets the voltage held by the holder to a predetermined voltage at predetermined time intervals.


Embodiments of the signal processing circuit and the A/D converter will be described with reference to the drawings below.


First Embodiment

First, a signal processing circuit according to the first embodiment will be described with reference to FIGS. 1-3, 4A-4D, 5A-5C, 6, 7A-7B, and 8-12. Here, FIG. 1 is a block diagram of a function configuration of the signal processing circuit according to the present embodiment. Also, FIG. 2 is a circuit diagram of an exemplary configuration of the signal processing circuit according to the present embodiment. As shown in FIG. 1, the signal processing circuit according to the present embodiment includes a rectifier 10 for generating a rectified voltage VA from an input voltage VIN, a holder 30 for holding an arbitrary voltage, a controller 20 for controlling a hold voltage VC held by the holder 30 based on the rectified voltage VA, and a setter 40 for setting the hold voltage VC to a predetermined voltage.


The input voltage VIN is input to the rectifier 10. The input voltage VIN is a signal in which a signal voltage VSIG is superimposed on a common-mode voltage VCM=VCM VSIG). The common-mode voltage VCM is a DC component of the input voltage VIN, and the signal voltage VSIG is an AC component of the input voltage VIN. For example, a sampled analog signal (voltage) can be exemplified as the input voltage VIN.


The rectifier 10 generates the rectified voltage VA which is equal to or higher than the common-mode voltage VCM by rectifying the input voltage VIN. More particularly, the rectifier 10 outputs the input voltage VIN without rectifying it when the input voltage VIN is equal to or higher than the common-mode voltage VCM. Also, the rectifier 10 converts the input voltage VIN lower than the common-mode voltage VCM into a voltage in which an absolute value |VSIG| of the signal voltage VSIG is added to the common-mode voltage VCM and outputs the converted voltage. Accordingly, the rectified voltage VA equal to or higher than the common-mode voltage VCM is output from the rectifier 10. That is, the rectified voltage VA satisfies VA=VIN=VCM VSIG in a case where VSIG≧0, and the rectified voltage VA satisfies VA=VCM−VSIG in a case where VSIG<0. Therefore, the rectified voltage VA generated by the rectifier 10 is a voltage in which the absolute value of the signal voltage VSIG is added to the common-mode voltage VCM (VA=VCM|VSIG|).


As shown in FIG. 2, the rectifier 10 includes input terminals 11 and 12, an amplifier 13, a subtraction circuit 14, switches 15 and 16, and a comparator 17. The input voltage VIN is input from the input terminal 11. The common-mode voltage VCM is input from the input terminal 12.


The amplifier 13 is connected to the input terminal 12. The amplifier 13 amplifies two times the common-mode voltage VCM input from the input terminal 12 and outputs the amplified voltage.


The subtraction circuit 14 is connected to the input terminal 11, and the input voltage VIN is input to the subtraction circuit 14. Also, the subtraction circuit 14 is connected to an output side of the amplifier 13, and the twice amplified common-mode voltage VCM is input to the subtraction circuit 14. The subtraction circuit 14 subtracts the input voltage VIN from the twice amplified common-mode voltage VCM and outputs the result. Therefore, a voltage output from the subtraction circuit 14 becomes 2VCM−VIN=VCM−VSIG.


The switch 15 (first switch) connects/opens (connects and opens) between the input terminal 11 and the controller 20. The switch 16 (second switch) connects/opens between the subtraction circuit 14 and the controller 20.


The comparator 17 is connected to input terminals 11 and 12, and each of the input voltage VIN and the common-mode voltage VCM is input to the comparator 17. The comparator 17 compares the magnitude of the input voltage VIN with that of the common-mode voltage VCM and controls opening/closing of the switches 15 and 16 based on the comparison result.


In particular, the comparator 17 turns ON the switch 15 and turns OFF the switch 16 in a case where the input voltage VIN is equal to or higher than the common-mode voltage VCM (VIN≧VCM). Accordingly, the rectified voltage VA output from the rectifier 10 is the input voltage VIN (VA=VIN=VCM+VSIG). Also, the comparator 17 turns OFF the switch 15 and turns ON the switch 16 in a case where the input voltage VIN is lower than the common-mode voltage VCM (VIN<VCM). Accordingly, the rectified voltage VA output from the rectifier 10 is a voltage output from the subtraction circuit 14 (VA=VCM−VSIG).


The comparator 17 outputs the comparison result between the input voltage VIN and the common-mode voltage VCM, that is, a signal DOUT indicating magnitude relation between the input voltage VIN and the common-mode voltage VCM. The signal DOUT output from the comparator 17 is, for example, a one-bit digital signal and is input to a restorator to be described below. A comparator can be used as the comparator 17.


In the above description, the rectifier 10 has generated the rectified voltage VA which is equal to or higher than the common-mode voltage VCM. However, the rectifier 10 may generate the rectified voltage VA which is equal to or lower than the common-mode voltage VCM. When the rectified voltage VA equal to or lower than the common-mode voltage VCM is generated, the rectifier 10 outputs the input voltage VIN equal to or lower than the common-mode voltage VCM without any processing. Also, the rectifier 10 converts the input voltage VIN higher than the common-mode voltage VCM into a voltage in which the absolute value |VSIG| of the signal voltage VSIG is subtracted from the common-mode voltage VCM and outputs the converted voltage. Accordingly, the rectified voltage VA equal to or lower than the common-mode voltage VCM is output from the rectifier 10.


That is, when VSIG<0, the rectified voltage VA satisfies VA=VIN=VCM+VSIG, and when VSIG≧0, the rectified voltage VA satisfies VA=VCM−VSIG. Therefore, the rectified voltage VA generated by the rectifier 10 is a voltage in which the absolute value of the signal voltage VSIG is subtracted from the common-mode voltage VCM (VA=VCM−|VSIG|). In the configuration of the rectifier 10 in FIG. 2, such a rectified voltage VA can be generated by reversing the control of opening/closing the switches 15 and 16 by the comparator 17.


The holder 30 is a unit for holding an arbitrary voltage. The holder 30 includes a capacitive element 31 as shown in FIG. 2. The capacitive element 31 has an arbitrary impedance and can hold the arbitrary voltage between a ground voltage and a power-supply voltage VDD. A side of a power supply (output side) of the capacitive element 31 is connected to the controller 20, the setter 40, and an output terminal 50 for outputting an output voltage VOUT of the signal processing circuit. Therefore, the hold voltage VC held by the holder 30 is output from the output terminal 50. That is, the hold voltage VC coincides with the output voltage VOUT (VC=VOUT).


The controller 20 is connected between the rectifier 10 and the holder 30. The rectified voltage VA is input from the rectifier 10 to the controller 20. The controller 20 controls the holder 30 based on the rectified voltage VA so that the hold voltage VC becomes equal to the rectified voltage VA. The controller 20 includes a current source 21, a switch 22, and a comparator 23 as shown in FIG. 2.


The current source 21 is connected to the side of the power supply (output side) of the capacitive element 31 so that a predetermined current I can be supplied to the capacitive element 31. The switch 22 (fourth switch) is provided between the current source 21 and the capacitive element 31 and connects/opens between the current source 21 and the capacitive element 31.


The rectified voltage VA is input to the comparator 23 from the rectifier 10. Also, the hold voltage VC is input to the comparator 23 from the holder 30. The comparator 23 compares the magnitude of the rectified voltage VA with that of the hold voltage VC and outputs a control signal φ1 based on the comparison result, and then, controls opening/closing of the switch 22.


In particular, the comparator 23 turns ON the switch 22 when the rectified voltage VA is higher than the hold voltage VC (VA>VC). Accordingly, the current source 21 supplies the current I to the capacitive element 31, and the capacitive element 31 is charged. Therefore, the hold voltage VC increases. Also, the comparator 23 turns OFF the switch 22 when the rectified voltage VA is equal to or lower than the hold voltage VC (VA≦VC). Accordingly, the current source 21 is opened, and the charge of the capacitive element 31 is terminated.


That is, the controller 20 increases the hold voltage VC by charging the capacitive element 31 when the rectified voltage VA is higher than the hold voltage VC, and the controller 20 terminates the charge when the hold voltage VC becomes equal to the rectified voltage VA. Accordingly, the controller 20 can control the hold voltage VC so as to be equal to the rectified voltage VA.


In the above description, the controller 20 is a controller of a current supply type which increases the hold voltage VC by supplying the current I to the holder 30. However, the controller 20 may be a controller of a current draw type which decreases the hold voltage VC by drawing the current I from the holder 30. In this case, the current source 21 is connected to a side of the ground of the capacitive element 31 so as to be able to draw a predetermined current I from the capacitive element 31 as shown in FIG. 3.


The comparator 23 in FIG. 3 turns ON the switch 22 when the rectified voltage VA is lower than the hold voltage VC (VA<VC). Accordingly, the current source 21 draws the current I from the capacitive element 31, and the capacitive element 31 is discharged. Therefore, the hold voltage VC decreases. Also, the comparator 23 turns OFF the switch 22 when the rectified voltage VA is equal to or higher than the hold voltage VC (VA≧VC). Accordingly, the current source 21 is opened, and the discharge of the capacitive element 31 is terminated.


That is, the controller 20 in FIG. 3 decreases the hold voltage VC by discharging the capacitive element 31 when the rectified voltage VA is lower than the hold voltage VC, and the controller 20 terminates the discharge when the hold voltage VC becomes equal to the rectified voltage VA. Accordingly, the controller 20 can control the hold voltage VC so as to be equal to the rectified voltage VA.


An arbitrary feedback element may be provided between the output terminal 50 and the input terminal of the comparator 23 to which the hold voltage VC is input. Accordingly, signal processing similar to that of a general feedback circuit can be added to the signal processing circuit according to the present embodiment.


The setter 40 sets the hold voltage VC of the holder 30 to a predetermined reset voltage VR. The reset voltage VR can be an arbitrary voltage equal to or lower than the common-mode voltage VCM when the rectified voltage VA is equal to or higher than the common-mode voltage VCM. In this case, it is preferable that the reset voltage VR be the common-mode voltage VCM or a voltage which is slightly lower than the common-mode voltage VCM. The setter 40 includes a voltage source 41 and a switch 42 as shown in FIG. 2.


The voltage source 41 is connected to the side of the power supply (output side) of the capacitive element 31 so as to be able to supply the reset voltage VR. The switch 42 (third switch) is provided between the voltage source 41 and the capacitive element 31 and connects/opens between the voltage source 41 and the capacitive element 31. A control signal φ2 input from outside controls the switch 42 to open/close at predetermined time intervals.


When the switch 42 is ON, the output side of the capacitive element 31 is connected to the voltage source 41 and the hold voltage VC is set to the reset voltage VR. On the other hand, when the switch 42 is OFF, the voltage source 41 is opened and the hold voltage VC is controlled by the controller 20 so as to be equal to the rectified voltage VA.


The reset voltage VR can be an arbitrary voltage equal to or higher than the common-mode voltage VCM when the rectified voltage VA is equal to or lower than the common-mode voltage VCM. In this case, it is preferable that the reset voltage VR be the common-mode voltage VCM or a voltage which is slightly higher than the common-mode voltage VCM.


Next, operation of the signal processing circuit according to the present embodiment will be described with reference to FIGS. 4A-4D, 5A-5C, 6, 7A-7B, and 8-12. It is assumed below that the signal processing circuit be applied to each stage of the pipeline A/D converter and the rectifier 10 rectify the input voltage VIN so that the rectified voltage VA becomes equal to or higher than the common-mode voltage VCM. Also, it is assumed that the input voltage VIN be a sampled analog signal and a voltage in which the signal voltage VSIG is superimposed on the common-mode voltage VCM.


When an analog signal is input to the A/D converter, the analog signal is sampled at predetermined sampling intervals. Here, a dashed line indicates the analog signal and a solid line indicates the sampled analog signal in FIG. 4A. The sampled analog signal becomes a discrete voltage which changes at sampling intervals as shown in FIG. 4A. This voltage is input to the signal processing circuit as the input voltage VIN.


The rectifier 10 rectifies the input voltage VIN and generates the rectified voltage VA. The rectified voltage VA generated by the rectifier 10 is input to the controller 20. Here, a dashed line indicates the input voltage VIN and a solid line indicates the rectified voltage VA in FIG. 4B. As described above, the rectifier 10 rectifies the rectified voltage VA so that the rectified voltage VA becomes equal to or higher than the common-mode voltage VCM. Therefore, the input voltage VIN lower than the common-mode voltage VCM is converted into an inverted voltage on the basis of the common-mode voltage VCM as shown in FIG. 4B (VA=VCM+|VSIG|).


Also, at this time, the comparator 17 of the rectifier 10 outputs the signal Dour indicating the magnitude relation between the input voltage VIN and the common-mode voltage VCM. The signal DOUT is a one-bit digital signal in FIG. 4C. The comparator 17 outputs HIGH when VIN VCM and outputs LOW when VIN<VCM. Restoration processing of the input voltage VIN using the signal DOUT will be described below.


The controller 20 controls the hold voltage VC of the holder 30 based on the input rectified voltage VA so as to be equal to the rectified voltage VA. Also, the setter 40 sets the hold voltage VC of the holder 30 to the reset voltage VR at the predetermined time intervals. The hold voltage VC of the holder 30 is output as the output voltage \LOUT.


By this operation, the signal processing circuit outputs the output voltage VOUT indicated in FIG. 4D relative to the rectified voltage VA. A dashed line indicates the rectified voltage VA and a solid line indicates the output voltage VOUT in FIG. 4D. The reset voltage VR is the common-mode voltage VCM in FIG. 4D. As described above, the reset voltage VR can be an arbitrary voltage equal to or lower than the common-mode voltage VCM. The output voltage VOUT of the signal processing circuit is input to a next stage provided in the pipeline A/D converter.


Here, operation of the controller 20, the holder 30, and the setter 40 in one cycle will be described below in detail with reference to Figs. FIGS. 5A, 5B, and 5C. The single cycle is from the input of the input voltage VIN to the signal processing circuit to the input of the next input voltage VIN. FIG. 5A is a partially enlarged diagram of FIG. 4D and enlarges and indicates a change of the output voltage VOUT (hold voltage VC) from when the input voltage VIN is input to when the next input voltage VIN is input. FIGS. 5B and 5C indicate states of the control signals φ1 and φ2 respectively, at each timing in FIG. 5A.


As shown in FIG. 5A, a period of one cycle from the input of the input voltage VIN to the input of the next input voltage VIN includes an amplification phase, a hold phase, and a reset phase. The amplification phase is a period from when the input voltage VIN is input to when the output voltage VOUT becomes equal to the rectified voltage VA. The hold phase is a period from when the output voltage VOUT becomes equal to the rectified voltage VA to when the output voltage VOUT is set to the reset voltage VR (=VCM). The reset phase is a period from when the output voltage VOUT is set to the reset voltage VR to when the next input voltage VIN is input.


First, the amplification phase will be described. When the input voltage VIN is input to the signal processing circuit, the rectifier 10 generates the rectified voltage VA and the rectified voltage VA is input to the controller 20. As shown in FIGS. 5B and 5C, the control signal φ1 is ON and the control signal φ2 is OFF in the amplification phase. That is, the switch 22 of the controller 20 is ON, and the switch 42 of the setter 40 is OFF.


Accordingly, the controller 20 supplies the current I from the current source 21 to the capacitive element 31 and controls the hold voltage VC so as to be equal to the rectified voltage VA. When the hold voltage VC becomes equal to the rectified voltage VA, the comparator 23 turns OFF the control signal φ1 and turns OFF the switch 22. Accordingly, the output voltage VOUT increases from the reset voltage VR to the rectified voltage VA in the amplification phase.


Next, the hold phase will be described. Both the control signals φ1 and φ2 are OFF in the hold phase. That is, the switch 22 of the controller 20 and the switch 42 of the setter 40 are OFF. Therefore, the holder 30 holds the hold voltage VC (=VA) controlled in the amplification phase. Accordingly, the rectified voltage VA is output as the output voltage VOUT during the hold phase.


Further, the reset phase will be described. The control signal becomes ON after a predetermined time from when the input voltage VIN is input to the signal processing circuit. Since the predetermined time is set so that the control signal φ2 is turned ON after the control signal φ1 is turned OFF, the control signal φ1 is OFF and the control signal φ2 is ON in the hold phase. That is, the switch 22 of the controller 20 is OFF, and the switch 42 of the setter 40 is ON. Therefore, the hold voltage VC of the holder 30 is set to the reset voltage VR. Accordingly, the reset voltage VR is output as the output voltage VOUT during the reset phase.


After a predetermined time from when the control signal φ2 is turned ON, the control signal φ2 is turned OFF. A timing when the control signal φ2 is turned OFF is synchronized with a timing when the next input voltage VIN is input to the signal processing circuit. When the control signal φ2 is turned OFF, the above-mentioned amplification phase starts again. That is, at a start time point of the amplification phase, the hold voltage VC is set to the reset voltage VR.


By repeating the above cycle, the signal processing circuit outputs the output voltage VOUT as indicated in FIG. 4D. At this time, in the signal processing circuit, the current is consumed in order to charge the capacitive element 31 from the reset voltage VR to the rectified voltage VA. When it is assumed that the reset voltage VR be the common-mode voltage VCM, a current value of the current source 21 be I, the signal voltage be VSIG, and the time of the amplification phase be TA, a charge voltage of the capacitive element 31 is as follows.










V
SIG

=


1
C





0

τ
A




l







t








[

formula





1

]







When it is assumed that the maximum amplitude of the signal voltage VSIG be VSIGMAX (=max |VSIG|), the maximum current consumption per cycle becomes I=max (C×(VIN−VCM))/T=C×VSIGMAX/TA.


Whereas, the traditional signal processing circuit shown in FIG. 6 does not include the rectifier 10 of the present embodiment. Therefore, the input voltage VIN as indicated in FIG. 7A is input to the controller 20. The minimum value of the input voltage VIN becomes VCM−VSIGMAX, and the maximum value of the input voltage VIN becomes VCM+VSIGMAX. In such a signal processing circuit, the reset voltage of the setter 40 is set to a voltage VB equal to or lowers than VCM−VSIGMAX (VB≦VCM−VSIGMAX) as shown in FIG. 7B. When the reset voltage VB is VCM−VSIGMAX, the maximum current consumption per cycle becomes I=max (C×(VIN−VB))/TA=2×C×VSIGMAX/TA.


As described above, compared with the traditional signal processing circuit, the signal processing circuit according to the present embodiment reduces the power consumption when the capacitive element 31 is charged/discharged. For example, the maximum current consumption is approximately half of that of the traditional signal processing circuit as described above. Therefore, the power consumption of the signal processing circuit can be reduced according to the present embodiment. Also, since a dynamic range of the comparator 23 can be reduced, the signal processing circuit according to the present embodiment can easily cope with voltage reduction according to miniaturization of manufacturing process.


The signal processing circuit according to the present embodiment may include a sampler 60 as shown in FIG. 9. The sampler 60 is provided on the input side of the rectifier 10, and the analog signal is input to the sampler 60. The sampler 60 samples the analog signal at predetermined sampling intervals. The analog signal sampled by the sampler 60 is input to the rectifier 10 as the input voltage VIN.


Also, the signal processing circuit according to the present embodiment may include a restorator 70 as shown in FIG. 10. The restorator 70 is provided on the output side of the holder 30, and the hold voltage VC is input from the holder 30 to the restorator 70. The digital signal DOUT is input from the rectifier 10 to the restorator 70. The restorator 70 restores the hold voltage VC to the input voltage VIN based on the digital signal DOUT.


For example, when the rectified voltage VA generated by the rectifier 10 satisfies VA=VCM+|VSIG|, the restorator 70 outputs the hold voltage VC as the output voltage VOUT without restoring it when the digital signal DOUT indicating VIN≧VCM is input (VOUT=VCM|VSIG|). On the other hand, when the digital signal DOUT indicating VIN<VCM is input to the restorator 70, the restorator 70 inverts the hold voltage VC relative to the common-mode voltage VCM. Then, the restorator 70 outputs the inverted voltage as the output voltage VOUT (VOUT=VCM−|VSIG|). Accordingly, the input voltage VIN is restored.


As shown in FIG. 11, the restorator 70 can include an amplifier 71 for amplifying twice the common-mode voltage VCM, a subtraction circuit 72 for subtracting the hold voltage VC from the output by the amplifier 71, and switches 73 and 74. The switches 73 and 74 are controlled by the digital signal DOUT. The switch 73 is turned ON when the digital signal DOUT (HIGH) indicating VIN≧VCM is input, and the switch 74 is turned ON when the digital signal DOUT (LOW) indicating VIN<VCM is input. With this configuration, the input voltage VIN can be restored.


Also, the signal processing circuit according to the present embodiment may include a signal processor 80 as shown in FIG. 12. The signal processor 80 is provided on the input side of the rectifier 10. The signal processor 80 performs arbitrary signal processing such as addition, subtraction, and differential and integral calculus to the input signal (voltage) and inputs the voltage to which the signal processing is performed to the rectifier 10 as the input voltage VIN. An adder circuit, a subtraction circuit, a differentiating circuit, an integrating circuit and the like can be used as the signal processor 80.


Second Embodiment

Next, a signal processing circuit according to the second embodiment will be described with reference to FIGS. 13 to 15. Here, FIG. 13 is a block diagram of a function configuration of the signal processing circuit according to the present embodiment. Also, FIG. 14 is a circuit diagram of an exemplary configuration of the signal processing circuit according to the present embodiment. As shown in FIG. 13, the signal processing circuit according to the present embodiment includes a differential rectifier 10A for generating rectified voltages VAP and VAM respectively from input voltages VINP and VINM, holders 30A and 30B for holding an arbitrary voltage, controllers 20A and 20B for respectively controlling hold voltages VCP and VCM held by the holders 30A and 30B based on the rectified voltages VAP and VAM, and a setter 40 for setting the hold voltages VCP and VCM to a predetermined voltage.


The input voltage VINP (first input voltage) and the input voltage VINM (second input voltage) are differentially input to the differential rectifier 10A. The input voltages VINP and VINM are signals in which a reverse phase signal voltage VSIG is superimposed on a common-mode voltage VCM(VINP=VCM+VSIG, VINM=VCM−VSIG). The common-mode voltage VCM is a DC component of the input voltages VINP and VINM, and the signal voltage VSIG is an AC component of the input voltages VINP and VINM. For example, a sampled analog signal (voltage) can be exemplified as the input voltages VINP and VINM.


The differential rectifier 10A generates the rectified voltage VAP (first rectified voltage) by rectifying the input voltage VINP. Also, the differential rectifier 10A generates the rectified voltage VAM (second rectified voltage) by rectifying the input voltage VINM. More particularly, the differential rectifier 10A outputs the voltage, which is equal to or higher than the common-mode voltage VCM, out of the input voltages VINP and VINM as the rectified voltage VAP without rectifying them. Accordingly, the differential rectifier 10A outputs the rectified voltage VAP equal to or higher than the common-mode voltage VCM. That is, the rectified voltage VAP satisfies VAP=VINP=VCM+VSIG when VSIG≧0, and the rectified voltage VAP satisfies VAP=VINM=VCM−VSIG when VSIG<0. Therefore, the rectified voltage VAP generated by the differential rectifier 10A is a voltage in which an absolute value of the signal voltage VSIG is added to the common-mode voltage VCM (VAP=VCM+|VSIG|).


Similarly, the differential rectifier 10A generates the rectified voltage VAM equal to or lower than the common-mode voltage VCM by rectifying the input voltages VINP and VINM. More particularly, the differential rectifier 10A outputs the voltage, which is equal to or lower than the common-mode voltage VCM, out of the input voltages VINP and VINM as the rectified voltage VAM without rectifying them. Accordingly, the differential rectifier 10A outputs the rectified voltage VAM equal to or lower than the common-mode voltage VCM. That is, the rectified voltage VAM satisfies VAM=VINM=VCM−VSIG when VSIG≧0, and the rectified voltage VAM satisfies VAM=VINP=VCM+VSIG when VSIG<0. Therefore, the rectified voltage VAM generated by the differential rectifier 10A is a voltage in which the absolute value of the signal voltage VSIG is subtracted from the common-mode voltage VCM (VAM=VCM−|VSIG|).


As shown in FIG. 14, the differential rectifier 10A includes input terminals 11A and 12A, switches 15A, 16A, 18A, and 19A, and a comparator 17A. The input voltage VINP is input from the input terminal 11A. The input voltage VINM is input from the input terminal 12A.


The switch 15A (sixth switch) is provided between the input terminal 11A and the controller 20A and connects/opens between the input terminal 11A and the controller 20A. The switch 16A (seventh switch) is provided between the input terminal 12A and the controller 20A and connects/opens between the input terminal 12A and the controller 20A. The switch 18A (eighth switch) is provided between the input terminal 11A and the controller 20B and connects/opens between the input terminal 11A and the controller 20B. The switch 19A (ninth switch) is provided between the input terminal 12B and the controller 20B and connects/opens between the input terminal 12B and the controller 20B.


The comparator 17A is connected to the input terminals 11A and 12A, and both the input voltages VINP and VINM are input to the comparator 17A. The comparator 17A compares the magnitude of the input voltage VINP with that of the input voltage VINM and controls opening/closing of the switches 15A, 16A, 18A, and 19A based on the comparison result.


In particular, the comparator 17A turns ON the switches 15A and 19A and turns OFF the switches 16A and 18A when the input voltage VINP is equal to or higher than the input voltage VINM (VINP≧VINM). Accordingly, the rectified voltage VAP output from the differential rectifier 10A becomes the input voltage VINP, and the rectified voltage VAM becomes the input voltage VINM (VAP=VINP, VAM=VINM). Also, the comparator 17A turns OFF the switches 15A and 19A and turns ON the switches 16A and 18A when the input voltage VINP is lower than the input voltage VINM (VINP<VINM). Accordingly, the rectified voltage VAP output from the differential rectifier 10A becomes the input voltage VINM, and the rectified voltage VAM becomes the input voltage VINP (VAP=VINM, VAM=VINP).


The comparator 17A may output the comparison result between the input voltages VINP and VINM, that is, a signal DOUT indicating magnitude relation between the input voltages VINP and VINM. The above-mentioned restorator 70 is connected to each of the output sides of the holders 30A and 30B, and each of the holders 30A and 30B inputs the signal DOUT to the connected restorator 70. Accordingly, the input voltages VINP and VINM can be respectively restored from the hold voltages VCA and VCB.


The holder 30A (first holder) and the holder 30B (second holder) are units for holding the arbitrary voltages. The holders 30A and 30B respectively include capacitive elements 31A and 30B as shown in FIG. 14. A low voltage side of the capacitive element 31A is connected to a high voltage side of the capacitive element 31B, and a connection node N is set to the common-mode voltage VCM. Therefore, the capacitive element 31A can hold the arbitrary voltage between the common-mode voltage VCM and a power-supply voltage VDD, and the capacitive element 31B can hold the arbitrary voltage between a ground voltage and the common-mode voltage VCM.


A side of a power supply (output side) of the capacitive element 31A is connected to the controller 20A and an output terminal 50A (first output terminal) for outputting an output voltage VOUTP. Therefore, the hold voltage VCA held by the holder 30A is output from the output terminal 50A. That is, the hold voltage VCA coincides with the output voltage VOUTP (VCA=VOUTP). Also, a side of the ground (output side) of the capacitive element 31B is connected to the controller 20B and an output terminal 50B for outputting an output voltage VOUTM. Therefore, the output terminal 50B outputs the hold voltage VCB (second hold voltage) held by the holder 30B. That is, the hold voltage VCB coincides with the output voltage VOUTM (VCB=VOUTM)


The controller 20A (first controller) is connected between the differential rectifier 10A and the holder 30A. The rectified voltage VAP is input from the differential rectifier 10A to the controller 20A. The controller 20A controls the holder 30A based on the rectified voltage VAP so that the hold voltage VCA becomes equal to the rectified voltage VAP. The controller 20A includes a current source 21A, a switch 22A, and a comparator 23A.


The current source 21A (first current source) supplies the current to the holder 30A and charges the holder 30A. The switch 22A (tenth switch) is provided between the current source 21A and the holder 30A and connects/opens between the current source 21A and the holder 30A. The comparator 23A (first comparator) compares the rectified voltage VAP with the hold voltage VCA and controls the opening/closing of the switch 22A based on the comparison result. That is, a configuration of the controller 20A is similar to that of the controller 20 of a current supply type according to the first embodiment. Therefore, the controller 20A compares the rectified voltage VAP with the hold voltage VCA, and when the rectified voltage VAP is higher than the hold voltage VCA, the controller 20A charges the holder 30A.


The controller 20B (second controller) is connected between the differential rectifier 10A and the holder 30B. The rectified voltage VAM is input from the differential rectifier 10A to the controller 20B. The controller 20B controls the holder 30B based on the rectified voltage VAM so that the hold voltage VCB becomes equal to the rectified voltage VAM. The controller 20B includes a current source 21B, a switch 22B, and a comparator 23B.


The current source 21B (second current source) draws the current from the holder 30B and discharges the holder 30B. The switch 22B (eleventh switch) is provided between the current source 21B and the holder 30B and connects/opens between the current source 21B and the holder 30B. The comparator 23B (second comparator) compares the rectified voltage VAM with the hold voltage VCB and controls the opening/closing of the switch 22B based on the comparison result. That is, a configuration of the controller 20B is similar to that of the controller 20 of a current draw type according to the first embodiment. Therefore, the controller 20B compares the rectified voltage VAM with the hold voltage VCB, and when the rectified voltage VAM is lower than the hold voltage VCB, the controller 20B discharges the holder 30A.


The setter 40 sets the hold voltage VCA of the holder 30A and the hold voltage VCB of the holder 30B to the common-mode voltage VCM. The setter 40 includes a voltage source 41 and switches 42A and 42B. The voltage source 41 supplies the common-mode voltage VCM.


The switch 42A (twelfth switch) is provided between the voltage source 41 and the output side of the capacitive element 31A and connects/opens between the voltage source 41 and the capacitive element 31A. When the switch 42A is ON, the output side of the capacitive element 31A is connected to the voltage source 41 and the hold voltage VCA is set to the common-mode voltage VCM. On the other hand, when the switch 42A is OFF, the voltage source 41 is opened and the hold voltage VCA is controlled by the controller 20A so as to be equal to the rectified voltage VAP.


The switch 42B (thirteenth switch) is provided between the voltage source 41 and the capacitive element 31B and connects/opens between the voltage source 41 and the capacitive element 31B. When the switch 42B is ON, the output side of the capacitive element 31B is connected to the voltage source 41 and the hold voltage VCB is set to the common-mode voltage VCM. On the other hand, when the switch 42B is OFF, the voltage source 41 is opened and the hold voltage VCB is controlled by the controller 20B so as to be equal to the rectified voltage VAM. The opening/closing of the switches 42A and 42B is controlled by the same control signal φ2. Therefore, the opening/closing of the switch 42A is synchronized with that of the switch 42B.


According to the present embodiment, with the configuration in which the signal processing circuit differentially inputs and outputs, the variation of the common-mode voltage VCM included in the input voltages VINP and VINM and the influence by a power supply noise and the like can be reduced. Also, since the differential rectifier 10A can include a comparator 17A and four switches, the configuration of the signal processing circuit can be simplified and the circuit size can be reduced. At the same time, the power consumption required for rectifying the input voltages VINP and VINM can be reduced.


The setter 40 can include a switch 42C (fourteenth switch) which connects/opens between the output side of the capacitive element 31A and the output side of the capacitive element 31B as shown in FIG. 15. When the switch 42C is ON, the capacitive elements 31A and 31B are short-circuited. Accordingly, the common-mode voltage VCM which is a voltage of the node N is output as the output voltages VOUTP and VOUTM. With this configuration, the setter 40 can be simplified and a circuit size can be further reduced.


Third Embodiment

Next, a signal processing circuit according to the third embodiment will be described with reference to FIG. 16. Here, FIG. 16 is a circuit diagram of an exemplary configuration of the signal processing circuit according to the present embodiment. As shown in FIG. 16, the signal processing circuit according to the present embodiment includes a differential rectifier 10A, controllers 20A and 20B, holders 30A and 30B, and a setter 40. Configurations of the differential rectifier 10A, the holders 30A and 30B, and the setter 40 are similar to those of the second embodiment.


In the present embodiment, the controllers 20A and 20B include a secondary battery 21C in common instead of the current sources 21A and 21B in the second embodiment. That is, the controller 20A includes the secondary battery 21C, a switch 22A, and a comparator 23A, and the controller 20B includes the secondary battery 21C, a switch 22B, and a comparator 23B. For example, a capacitive element in which a predetermined voltage is charged can be used as the secondary battery 21C.


In the present embodiment, when the switches 22A and 22B are ON, a current discharged from the capacitive element 31B is charged to the capacitive element 31A via the secondary battery 21C. Therefore, the signal processing circuit according to the present embodiment can realize operation similar to that of the second embodiment.


With this configuration, configurations of the controllers 20A and 20B can be simplified and a circuit size can be reduced. Also, since current sources of the controllers 20A and 20B are not necessary, power can be reduced.


The signal processing circuit according to each embodiment above can be applied to a pipeline A/D converter and a successive comparison A/D converter. In this case, it is preferable that a sampled single-phase input analog signal be input to the signal processing circuit according to the first embodiment as the input voltage VIN. Also, it is preferable that a sampled differential input analog signal be input to the signal processing circuit according to the second and third embodiments as each input voltages VINP and VINM. The power consumption of the A/D converter can be reduced by having the signal processing circuit according to the embodiments described above. Also, the circuit size can be reduced, and the A/D converter can be miniaturized.


While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and systems described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.

Claims
  • 1. A signal processing circuit comprising: a rectifier to generate a rectified voltage by rectifying an input voltage in which a signal voltage is superimposed on a common-mode voltage;a holder to hold a voltage;a controller to control the holder so as to hold a voltage according to the rectified voltage generated by the rectifier; anda setter to set the voltage held by the holder to a predetermined voltage at predetermined time intervals.
  • 2. The circuit according to claim 1, wherein the rectifier generates a voltage in which an absolute value of the signal voltage is added to the common-mode voltage or a voltage in which the absolute value of the signal voltage is subtracted from the common-mode voltage as the rectified voltage.
  • 3. The circuit according to claim 1, wherein the rectifier includesan input terminal to which the input voltage is input,an amplifier to amplify the common-mode voltage,a subtraction circuit to subtract the input voltage from the common-mode voltage amplified by the amplifier,a first switch to connect and open between the input terminal and the controller,a second switch to connect and open between the subtraction circuit and the controller, anda comparator to control the first and second switches based on a comparison result between the input voltage and the common-mode voltage.
  • 4. The circuit according to claim 1, wherein the rectifier generates a signal indicating a comparison result between the input voltage and the common-mode voltage.
  • 5. The circuit according to claim 4, further comprising; a restorator to restore the input voltage from an output voltage based on the signal generated by the rectifier.
  • 6. The circuit according to claim 1, wherein the holder includes a capacitive element.
  • 7. The circuit according to claim 1, wherein the setter includes a voltage source to supply a predetermined voltage, anda third switch to connect and open between the voltage source and the holder.
  • 8. The circuit according to claim 1, further comprising: a sampler to sample an analog signal, whereina voltage sampled by the sampler is input to the rectifier as the input voltage.
  • 9. The circuit according to claim 1, further comprising: a signal processor to perform predetermined signal processing to the input voltage, whereina voltage performed the predetermined signal processing by the signal processor is input to the rectifier as the input voltage.
  • 10. The circuit according to claim 1, wherein the controller compares the rectified voltage with the voltage held by the holder and increases the voltage held by the holder when the rectified voltage is higher than the voltage held by the holder.
  • 11. The circuit according to claim 10, wherein the controller includesa current source to charge the holder,a fourth switch to connect and open between the current source and the holder, anda comparator to control the fourth switch based on a comparison result between the rectified voltage and the voltage held by the holder.
  • 12. The circuit according to claim 1, wherein the controller compares the rectified voltage with the voltage held by the holder and decreases the voltage held by the holder when the rectified voltage is lower than the voltage held by the holder.
  • 13. The circuit according to claim 12, wherein the controller includesa current source to discharge the holder,a fifth switch to connect and open between the current source and the holder, anda comparator to control the fifth switch based on a comparison result between the rectified voltage and the voltage held by the holder.
  • 14. A signal processing circuit comprising: a differential rectifier to generate first and second rectified voltages by rectifying first and second input voltages in which a signal voltage is superimposed on a common-mode voltage;a first holder to hold a voltage;a first controller to control the first holder so as to hold a voltage according to the first rectified voltage generated by the differential rectifier;a second holder to hold a voltage;a second controller to control the second holder so as to hold a voltage according to the second rectified voltage generated by the differential rectifier; anda setter to set the voltages held by the first and second holders to predetermined voltages at predetermined time intervals.
  • 15. The circuit according to claim 14, wherein the differential rectifier generates a voltage in which an absolute value of the signal voltage is added to the common-mode voltage as the first rectified voltage and generates a voltage in which the absolute value of the signal voltage is subtracted from the common-mode voltage as the second rectified voltage.
  • 16. The circuit according to claim 14, wherein the differential rectifier includesa first input terminal to which the first input voltage is input,a second input terminal to which the second input voltage is input,a sixth switch to connect and open between the first input terminal and the first controller,a seventh switch to connect and open between the second input terminal and the first controller,an eighth switch to connect and open between the first input terminal and the second controller,a ninth switch to connect and open between the second input terminal and the second controller, anda comparator to control the sixth, seventh, eighth, and ninth switches based on a comparison result between the first input voltage and the second input voltage.
  • 17. The circuit according to claim 14, wherein the first controller compares the first rectified voltage with the voltage held by the first holder and charges the first holder when the first rectified voltage is higher than the voltage held by the first holder, andthe second controller compares the second rectified voltage with the voltage held by the second holder and discharges the second holder when the second rectified voltage is lower than the voltage held by the second holder.
  • 18. The circuit according to claim 14, wherein the first controller includesa first current source to charge the first holder,a tenth switch to connect and open between the first current source and the first holder, anda first comparator to control the tenth switch based on a comparison result between the first rectified voltage and the voltage held by the first holder, andthe second controller includesa second current source to discharge the second holder,an eleventh switch to connect and open between the second current source and the second holder, anda second comparator to control the eleventh switch based on a comparison result between the second rectified voltage and the voltage held by the second holder.
  • 19. The circuit according to claim 18, wherein the first and second current sources share the secondary battery.
  • 20. The circuit according to claim 14, wherein the setter includesa voltage source to supply a predetermined voltage,a twelfth switch to connect and open between the voltage source and the first holder, anda thirteenth switch to connect and open between the voltage source and the second holder.
  • 21. The circuit according to claim 14, wherein the setter sets the voltages held by the first and second holder to the common-mode voltage.
  • 22. The circuit according to claim 14, wherein the setter includes a fourteenth switch to connect and open between the first holder and the second holder.
  • 23. An A/D converter comprising: the circuit according to claim 1.
Priority Claims (1)
Number Date Country Kind
2014-014414 Jan 2014 JP national