JPH0518707Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a rectifier circuit, particularly one comprising an amplifier circuit comprising an operational amplifier.

Conventional technology Conventionally, AC input signals are converted to DC, and
If it is desired to eliminate the forward drop caused by the diode, a full-wave rectifier circuit as shown in FIG. 2 is used. In the figure, 10 is an AC input terminal, and 12 is a DC output terminal. Reference numerals 14 and 16 denote a first amplifier circuit and a second amplifier circuit that are interposed between the input and output terminals 10 and 12 and constitute a full-wave rectifier circuit. 18 is a first operational amplifier which is the center of the first amplifier circuit 14;
20 is its input resistance (resistance value R ₁ ), 22 and 24 are respective feedback resistors (resistance values are R ₂ and R ₃ respectively), 26,
A diode 28 is connected between one end of each feedback resistor 22, 24 and the output terminal a of the first operational amplifier 18. Note that the diodes 26, 2
8 is connected in the opposite direction to each feedback resistor 22, 24. Therefore, two negative feedback circuits having different directivity are connected in parallel to the first operational amplifier 18. 30 is a second operational amplifier which is the center of the second amplifier circuit 16, 32 and 34 are input resistors thereof (resistance values are R ₄ and R ₅ respectively), and 36 is a feedback resistor (resistance value is R ₆ ). In addition, the input resistance 32
is the output terminal of the first amplifier circuit 14, that is, the feedback resistor 22
and the connection point b of the diode 26.
Further, the input terminal 34 is connected to the AC input terminal 10.

Problems to be Solved by the Invention If such a full-wave rectifier circuit is adopted, it is possible to perform full-wave rectification of even small-level signals with relative accuracy. However, in the output of the first operational amplifier 18, the impedance acting as a load is different between the negative half wave waveform and the positive half wave waveform. That is, for a negative half-wave waveform, the second operational amplifier 30
Due to the imaginary short of , its inverting input terminal (-) becomes ground potential, so the input resistance 32
becomes a load. Also, for a positive half-wave waveform, there is no load and the impedance is zero. If the impedance of the load differs greatly in this way, not only the frequency characteristics of the elements of the first operational amplifier 30 but also the
The frequency characteristics of the first amplifier circuit 14 are also inferior.

The present invention was developed by focusing on these conventional problems, and by improving the load impedance of the operational amplifier that constitutes the amplifier circuit,
The purpose is to provide a rectifier circuit with good frequency characteristics.

Means for Solving the Problems Means for achieving the above object will be described below with reference to FIG. 1, which corresponds to an embodiment.

This rectifier circuit includes two negative feedback circuits having different directivities connected in parallel and an amplifier circuit 42 comprising an operational amplifier 18 which takes an output from one of the negative feedback circuits. And the amplifier circuit 4
A grounded load impedance _Rz is connected to the negative feedback circuit that is not used as the output point b of No. 2 at the same position c as the output point b.

Effect The above means works as follows.

Two negative feedback circuits having different directivity are connected in parallel, and the output point b is connected to the negative feedback circuit that is not used as the output point b of the amplifier circuit 42, which is made up of an operational amplifier 18 that takes the output from one of the negative feedback circuits. When a grounded load impedance R _z is connected to the same position c, at the output of the operational amplifier 18, the load impedance R ₄ ,
It is possible to make R _z not much different.
Therefore, the operation of the operational amplifier 18 tends to be stable over one cycle, and not only the frequency characteristics of the element itself but also the frequency characteristics of the amplifier circuit 42 are improved.

Embodiments Hereinafter, embodiments of the present invention will be described based on the accompanying drawings.

FIG. 1 is a diagram showing a full-wave rectifier circuit according to an embodiment of the present invention. In the figure, the same parts corresponding to the conventional example are given the same reference numerals. In the conventional example, nothing is connected to the negative feedback circuit to which the input resistor 32 of the first amplifier circuit 14 is not connected, except for the diode 28 and feedback resistor 24 that constitute it, whereas in this embodiment, the operational amplifier 18 is connected thereto. The difference is that a grounded impedance serving as a load is connected. That is, the feature of this embodiment is that a grounded load impedance (its impedance value R _z ) 40 is connected to the connection point c between the diode 28 and the feedback resistor 24, and the first amplifier circuit 42
The point is that it constitutes.

In such a full-wave rectifier circuit, when an AC signal is applied from the input terminal 10 to the first amplifier circuit 42, the signal enters the first operational amplifier 18 through the input resistor 20. At this time, negative feedback is applied through the diode 26 and the feedback resistor 22, the diode 28 and the feedback resistor 24, etc. As a result, a negative half-wave waveform is output to the output terminal (output point) b of the first amplifier circuit 42. Also, at the connection point c between the diode 28 and the feedback resistor 24 (same position as the output point b),
A positive half-wave waveform is output. At this time, in the output of the first operational amplifier 18, the load impedance can be made not to differ much between the negative half-wave waveform and the positive half-wave waveform. For example, if the impedance value R _z of the load impedance 40 is set equal to the resistance value R ₄ of the input resistor 32 (R _z = R ₄ ), the output of the first operational amplifier 18 has a value for both positive and negative half-wave waveforms. Identical loads are connected. Therefore, the operation of the first operational amplifier 18 is likely to be stable over one cycle, and deterioration of frequency characteristics due to unbalance between them is eliminated. As a result, not only the frequency characteristics of the element itself of the first operational amplifier 18 but also the frequency characteristics of the first amplifier circuit 42 are improved. Furthermore,
When the input resistor 20 and the feedback resistors 22 and 24 have the same resistance value (R ₁ = R ₂ = R ₃ ), the gain of the first amplifier circuit 42 is set to 1, and the positive AC signal input to the input terminal 10 is It is possible to invert only the polarity of the waveform on the side and output it to the output terminal b of the first amplifier circuit 42 with the same peak value. In addition, the diode 28 and the feedback resistor 24
Similarly, the negative side waveform of the AC signal input to the input terminal 10 is outputted to the connection point c with the polarity inverted. Next, when such a negative half-wave waveform from the first amplifier circuit 42 is applied to the second amplifier circuit 16, the signal enters the second operational amplifier 30 through the input resistor 32. At the same time, the AC signal is also input to terminal 1.
0 to the second amplifier circuit 16, the signal is applied to the second operational amplifier 30 through the input resistor 34.
to go into. Further, these inputs are subjected to negative feedback through a feedback resistor 36, and are added together, and the second operational amplifier 3
Output from 0. This is the output of the second amplifier circuit 16 and appears at the output terminal 12 as a positive full-wave rectified waveform. At this time, the ratio of the resistance values of the input resistors 32 and 34 is set to 1:2 (R ₄ :R ₅ =1:2), and the resistance values of the input resistor 34 and the feedback resistor 36 are set to be equal (R ₅ =R ₆ ), the gain of the second amplifier circuit 16 is 2 for a negative signal input from the input resistor 32, and 1 for an AC signal input from the input resistor 34.
Therefore, as a result of the addition, the AC signal input to the input terminal 10 is outputted to the output terminal 12 as a positive full-wave rectified waveform with the same magnitude.

Note that the second operational amplifier 3 is connected through the input resistor 32.
The half wave waveform that enters 0 is connected to the diode 28 and the feedback resistor 2.
4, a negative full-wave rectified waveform is output to the DC output terminal 12. At this time, a grounded load impedance 40 is connected to the connection point b.

In addition, not only the full-wave rectifier circuit described above but also a half-wave rectifier circuit using only the first amplifier circuit 42, a grounded impedance serving as the load of the operational amplifier is connected to a negative feedback circuit to which no load impedance is connected. This will have the same effect.

Effects of the invention According to the invention described above, a rectifier circuit with good frequency characteristics can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a full-wave rectifier circuit according to an embodiment of the present invention. FIG. 2 is a diagram of a conventional full-wave rectifier circuit. 10, 12... Input/output terminal, 18, 30... First and second operational amplifier, 20, 32, 34... Input resistor, 22, 24... Feedback resistor, 26, 28...
Diode, 40... Grounded load impedance, 4
2, 16...first and second amplifier circuits.

Claims (1)

[Claims for Utility Model Registration] (1) In a rectifier circuit equipped with an amplifier circuit consisting of an operational amplifier in which two negative feedback circuits having different directivity are connected in parallel and the output is taken from one of the negative feedback circuits, A rectifier circuit characterized in that a grounded load impedance is connected to the other negative feedback circuit that is not the output point of the amplifier circuit at the same position as the output point. (2) The grounded load impedance of the operational amplifier is
2. The rectifier circuit according to claim 1, wherein the output is equal to the load impedance of the amplifier circuit to which it is connected.