1. Field of the Invention
The present invention relates to an input circuit. In particular, the present invention relates to an input circuit having an offset voltage adjustment circuit.
2. Description of Related Art
In recent years, semiconductor apparatuses have been required to have a smaller size and reduced power consumption due to an electric signal having a higher speed used in an electronic device and a larger circuit size of the entire semiconductor apparatus used in an electronic device. In accordance with this, reducing the power consumption of a basic circuit configuration of a semiconductor apparatus has been important. In particular, reducing the power consumption of an input circuit including a buffer circuit for handling an analog input signal has been important because such an input circuit is a continuous time processing system.
Such an input circuit is generally inserted between a precedent stage circuit such as an analog input signal source and a subsequent stage circuit such as an analog/digital converter. Such an input circuit has a function to adjust the impedance and offset voltage for the precedent stage circuit and the subsequent stage circuit.
Next, with reference to
The technique as described above is also disclosed in U.S. Pat. No. 7,126,377 for example.
The present inventors have found a problem that it has now been discovered that the buffer circuit requires three resistances (114, 116, and 110) and thus the power consumption by the resistances is high.
An exemplary aspect of an embodiment of the present invention is an input circuit which includes a first buffer circuit having an output signal terminal connected to an output, a capacitor having one end connected to an input signal terminal, and the other end connected to an input of the first buffer circuit; a first differential amplification circuit receiving a voltage of a first external power source terminal and an output of a second buffer circuit, a second differential amplification circuit receiving a voltage of a second external power source terminal and an output of a third buffer circuit, a first resistance having one end connected to an output of the first differential amplification circuit, and the other end connected between the capacitor and the first buffer circuit, and a second resistance having one end connected to an output of the second differential amplification circuit, and the other end connected between the capacitor and the first buffer circuit. Wherein, an input of the second buffer circuit is connected to the output of the first differential amplification circuit, and an input of the third buffer circuit is connected to the output of the second differential amplification circuit.
The above and other exemplary aspects, advantages and feature will be more apparent from the following description of certain exemplary embodiments taken in conjunction with the accompanying drawings, in which:
The first exemplary embodiment of the present invention will be described with reference to
Next, the configuration of the present invention will be described with reference to
Next, with reference to
Thus, when the DC bias resistances 10 and 15 have the same resistance value, the voltage of a node 18 is to be (Vout1+Vout2)/2=(VRT+VRB)/2c. Thus, the voltage of the output signal terminal 5 is to be c·((VRT+VRB)/2c))=(VRT+VRB)/2. Thus, the intermediate voltage between the external reference voltages VRT and VRB is output.
The replica buffer circuits 35 and 30 desirably have the same voltage gain as that of the main buffer circuit 20. For example, the replica buffer circuits 35 and 30 may have the same circuit configuration as that of the main buffer circuit 20. When the replica buffer circuits 35 and 30 have the same voltage gain as that of the main buffer circuit 20, an output signal having center voltage made by the resistance voltage division between the external reference voltages VRT and VRB with using DC bias resistance 10 and 15 can be generated. When the replica buffer circuits 35 and 30 have a different voltage gain from that of the main buffer circuit 20, the ratio of the resistance value of the DC bias resistance 10 and 15 can be changed to adjust the center voltage.
For example, when assuming that the main buffer circuit 20 has a voltage gain C1, the replica buffer circuits 35 and 30 have a voltage gain C2, and the ratio between the resistance values of the DC bias resistances 10 and 15 is α, then the voltage of the node 18 is (α·VRB+VRT)/(1+α)/C2. Thus, the voltage of the output signal terminal 5 is (α·VRB+VRT)/(α+1)·C1/C2. When this voltage is to be (VRT+VRB)/2, α=(C2/C1·(VRT+VRB)/2−VRT)/(VRB−C2/C1·(VRT+VRB)/2) needs to be satisfied. With the resistance ratio as described above, the voltage of (VRT+VRB)/2 can be obtained as an output voltage even when C1 and C2 are not equal.
Next, a mechanism will be described in which the first exemplary embodiment of the present invention having the same chip size provides lower power consumption when compared with the circuit of
Here, the output impedances of the differential amplification circuit 140 and the differential amplification circuits 45 and 40 for the node 118 and the node 18 are set to be equal.
The output impedance Rout in the output terminal 74 is calculated based on Rout=R1//R2. Here, R1 and R2 represent an output impedance between the source and the drain of a PMOS transistor 78 and an NMOS transistor 76. R1 and R2 can be calculated by a square-law characteristic formula for the gate voltage of the drain current in the MOS transistor. The drain current Id is given by Id=1/2·μ·Cox·(W/L)·(Vgs−Vth)2·(1+λ·Vds). Here, μ represents an electronic mobility, Cox represents a unit capacity, W represents a gate width, L represents a gate length, Vgs−Vth represents an effective gate voltage, and Vds represents a voltage between a source and a drain. λ represents a coefficient of Vds in a saturation region. Here, output impedances R1 and R2 are given by ∂Vds/∂Id.
Based on the above, the output impedances R1 and R2 is found as R1=1/(λp·Id) and R2=1/(λn·Id). Here, λ of PMOS transistor is assumed as λp and λ of NMOS transistor is assumed as λn. From these formulae, the output impedance Rout of the differential amplification circuit is consequently Rout=1/(λp·Id+λn·Id)∝2/Id.
In order to provide the same output impedance of the differential amplification circuits for the node 18 and the node 118, the resistance value R of the resistance 110 may be equal to the total resistance values of the resistance 10 and the resistance 15 and the total output impedances of the differential amplification circuits 45 and 40 may be equal to the output impedance of the differential amplification circuit 140.
Since Rout∝1/Id is established, drain current Id of the differential amplification circuits 45 and 40 is a half of the drain current Id of the differential amplification circuit 140. This means that, when the same current density is used to operate the differential amplification circuits 45 and 40 and the differential amplification circuit 140, the gate widths of the differential amplification circuits 45 and 40 may be a half of the gate width of the differential amplification circuit 140. Similarly, the current and the gate width of the replica buffer circuits 35 and 30 may be a half of the current and the gate width of the replica buffer circuit 130.
From the above, the total drain current of the differential amplification circuits 45 and 40 of
In order to allow a resistance value R of resistance 110 to be equal to the total resistance values of resistance 10 and resistance 15, the resistance values of the resistances 10 and 15 may be 2R.
Since a size of resistance is roughly proportional to a resistance value, in order to achieve the same chip size (i.e., the same resistance area), the total resistance value may be at the same level in
In this case, the total of the power consumed by the resistance of
The power consumption at the resistances 114 and 116 is found as (2Vr)2/(2·3R/2)=4Vr2/3R. The power consumption at the DC bias the resistance 110 on the other hand is found as Vs2sin2 (ωt))/R because the voltage applied to the DC bias the resistance 110 can be written to be Vs·sin(ωt). With a time average method, it can be found as Vs2/2R at the DC bias the resistance 110. Thus, the total power consumption by the resistance of the circuit of
On the other hand, the power consumption at the resistance in the circuit of
As can be seen from these results, the circuit of
Another effect is also obtained. That is, the external reference voltage terminals 65 and 60 are connected to the differential input circuits 45 and 40 having high input impedance and thus substantially no current flows in an external reference voltage. In the related example shown in
In the main buffer circuit and the replica buffer circuit of the second exemplary embodiment of the present invention, an input signal voltage input to the input the terminal 9 is applied between the gate and the source of the NMOS transistor 86 and drain current flows in accordance with the voltage between the gate and the source. Current having the same value as that of this drain current flows to the drain of the PMOS transistor 84 by the PMOS transistors 82 and 84 constituting a current mirror circuit. The drain current of the PMOS transistor 84 flows between the drain and the source of the NMOS transistor 88 and a gate voltage depending on the current value is output to the output terminal 8.
In the main buffer circuit and the replica buffer circuit of the second exemplary embodiment of the present invention, the input-side NMOS transistor 86 is separated from the output-side NMOS transistor 88 to isolate the input from the output. This suppresses an output impedance of a precedent stage circuit connected to the input the terminal 9 and an input impedance of a subsequent stage circuit connected to the output terminal 8 from interfering each other. Thus, even when the subsequent stage circuit has a low input impedance to flow current, the current at the output-side of the precedent stage circuit does not change. Thus, a new effect can be obtained according to which a disadvantage such as a reduced signal voltage due to increased current can be prevented.
The main buffer circuit 20 and the replica buffer circuits 35 and 30 arranged so as to be adjacent to one another can minimize the influence by the variation in the voltage gains due to the variation in a wafer plane of a transistor. The resistances 10 and 15 for DC buffer also arranged so as to be adjacent to each other can minimize the influence by the variation in a resistance value due to the variation in the wafer plane. Thus, a new effect can be obtained according to which variation of a center voltage of a buffer circuit due to process variation can be suppressed.
When the replica buffer circuits 35 and 30 are arranged at symmetric positions to the main buffer circuit 20 as shown in
The first, second and third exemplary embodiments can be combined as desirable by one of ordinary skill in the art.
While the invention has been described in terms of several exemplary embodiments, those skilled in the art will recognize that the invention can be practiced with various modifications within the spirit and scope of the appended claims and the invention is not limited to the examples described above.
Further, the scope of the claims is not limited by the exemplary embodiments described above.
Furthermore, it is noted that, Applicant's intent is to encompass equivalents of all claim elements, even if amended later during prosecution.
Number | Date | Country | Kind |
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2008-075424 | Mar 2008 | JP | national |
The present application is a Continuation Application of U.S. patent application Ser. No. 12/382,542, filed on Mar. 18, 2009, which is based on Japanese patent application No. 2008-075424, filed on Mar. 24, 2008, the entire contents of which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 12382542 | Mar 2009 | US |
Child | 12923340 | US |