DE2123047A1 - DC amplifier circuit - Google Patents

Description

DIPL.-PHYS. ROBERT MÜNZHUBER

PATENT LAWYERS

8 MUNICH 22 Wl DENMAYERSTRASSE 6 TEL. (0811) 222530-295192

May 10, 1971 Our reference: A 178 71 / Pp / gb

IWASAKI TSUSHINKI KABUSHIKI KAISHA, 1-7-41, Kugayama, Suginami-Ku, Tokyo-To, Japan

DC amplifier circuit

The invention relates to a direct current amplifier circuit.

To date, DC amplifier circuits have commonly been included for amplifying input signals DC signals are used. In this case there will be stability and non-drift in the DC amplifier demands. Chopper amplifiers are often used to reduce the drift value. However the drift is not insignificant even in a chopper amplifier. Also is the bandwidth of a chopper amplifier narrow. The above-mentioned drift can be switched off by a drift compensation, which is done manually

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is carried out by a zero adjustment. However, it is extremely difficult to get one with every reinforcement to achieve such a comparison by hand. In addition, it is very difficult to get an exact balance by hand Get results.

It is therefore an object of the invention to provide a direct current amplifier circuit to create, which is able to overcome the above-mentioned disadvantages of the previous Type off, and which is suitable, a simple way of zero voting with certainty and without impairment a wide band characteristic.

A DC amplifier circuit according to the invention is provided with an input terminal with an amplifier stage connected to the input terminal is coupled, and with an output terminal which is connected to this amplifier stage. According to the Feature of this invention is a first switch between input terminal and amplifier stage is provided while the amplifier stage has a first direct current amplifier connected to the output of the first switch and a differential amplifier, of which an input is connected to the output of the first direct current amplifier. There is also a drift memory

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circuit between the output of the differential amplifier and the other input of the differential amplifier for a feedback of the output of the differential amplifier when the first switch is at ground, and for the continuous generation of a voltage as a feedback signal which is substantially equal to the Drift voltages of the first DC amplifier and the differential amplifier is transformed accordingly of the input of the differential amplifier.

The principle, structure and mode of operation of the circuit according to the invention will become apparent from the following description and the accompanying drawings more clearly.

In the drawing, embodiments of the invention are shown, for example, namely show:

Figures 1, 2 and 3 are block diagrams of various

Embodiments of the invention.

One in Pig. 1 illustrated embodiment of Invention consists of an input connector 1 for receiving the input signal, of a switch 2, which establishes a connection between a basic terminal 3 and one of the two terminals 4 or 5

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a first DC amplifier 7 with an input terminal 6, from a second DC amplifier 10 with two input terminals 8 and 9 and an output terminal 11, from a third amplifier 13 with an input terminal 12 and an output terminal l4 a switch 15 for switching the output of the direct current amplifier 13 on or off and a capacitor 16. In this case, the corresponding phases of terminals 8 and reversed to each other, whereas the corresponding phases of terminals 9 ^{un <} 3 H are the same. In addition, terminals 12 and 14 have the same phase relationship.

In the in Pig. I embodiment it is assumed that the gain of the first direct current amplifier 7j is a value of the drift converted as a function of the input terminal 6, the gain of the second direct current amplifier 10, a value of the drift converted as a function of the input terminal 8, the gain of the third DC amplifier 13 and a value of the drift converted as a function of the input ^terminal 12 have ^{the designations u} l * ^V l * ^U 2 ' ^V 2 * ^u "5 deciilun.

It is also assumed that the voltages on the

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Terminals 9 and 11 have the values V ₂ and V, respectively. When switch 2 is in the position in which it connects terminals 3 and 5, the following equations are fulfilled:

ν = ν u + ν + (ι)

^V gl ^V 1 ^U 1 ^{+ V} 2 ^u;

V _e2 = (V + V,) u (2)

V ₀ = U ₂ (V. - V ₂ ) (3)

In this case, the value V- corresponds to the input voltage at terminal 8. From the above equations the following equations can be derived:

1 +

(V ₁ U ₁ - V ₃ U ₃ + V ₂ )

U ₂ u,
^v g2 ⁼ (V ₁ U ₁ - V ₃ U ₃ + V ₂ ) + V ₃ U _3. (5)

If the product UgU-, is determined to be is much larger than one, equations (4) and (5) can accordingly be written as follows:

V ₂

V = -v, +
³

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In addition, if the gain u_. enough great versus gain & and equally significant is greater than one, the following equation is obtained:

(8th)

In other words, the equivalent input voltage V. of terminal 8 is equal to the voltage of Terminal 9

In this case, the switch 15 is switched off, while an input signal V. is applied to the input terminal 1 after switching over the switch 2, so that the terminals 3 and 4 are now connected. When a drift voltage defined by the equation (5) or (7) * is stored in the capacitor 16, a voltage at the output terminal 11 can be determined by adding a drift defined by the equation (4), (6) or (8) and a Product U ₁ UpV. can be obtained. For example, the following output signal V is obtained at the output terminal 11 in the case of equation (8).

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^V o - Wl * ^V 3 ....... (9)

In this pall, the voltage (-V,) is a drift in the output voltage. If, in the embodiment shown in FIG. 1, a drift _r storage circuit 17 (ie the amplifier 13, the switch 15 and the capacitor 16) and the switch 2 are omitted and the input voltage V. is applied to the terminal 6 after the terminal 9 is earthed a common DC amplifier is obtained. In this case an output voltage V is obtained at the output

OcL

terminal 11, as follows:

^V oa = ^U l ^U 2 ^V i ^{+ U} 1 ^U 2 ^V 1 ^{+ U} 2 ^V 2

A drift in the output voltage has a value of (U ₁ Up V. + Up V). Accordingly, it is easy to see that a drift voltage in the output voltage has been substantially reduced according to the invention.

The following conditions serve as an example: V ₁ = Vp = V; u. = 1; Up = 1000j and u., = 100. The output voltage ^v ~ _o obtained according to the type of direct current amplification just mentioned can thus be expressed:

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^V oa ^{Ä 100} ° ^V i ^{+ 200} ° ^V i ..... (H)

In contrast, there is an output voltage V at the invention according to Glethstrom amplifier from:

V ₀ = 1000 V ₁ -V ₁ (12)

As can be easily seen from equations (II) and (12), a drift in the output voltage is reduced to a two-thousandth compared to a drift in the conventional amplifiers while the input signal V _{1 is} amplified a thousand times.

If the DC amplifier 13 » as shown in FIG. 2 is omitted and the output terminal 11 is connected to the switch 15, the following conditions are obtained: V-, = 0 and u = 1. Accordingly, if the following conditions are accepted: V. - Y; u. = 1 and Up = 1000, according to equation (6) the output voltage V can be defined as:

= 1000 V ₁ + 2

In this case there is a drift compared to that case shown by equation (12) twofold while

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this drift by a thousandth in comparison with a conventional DC amplifier, defined by equation (ll), is decreasing. As mentioned above, the third DC amplifier 13 can therefore be omitted.

In addition, the embodiment shown in FIG. 1 can be modified from that shown in FIG which the third DC amplifier 13 between the terminal 9 and the capacitor 16 are connected, the switch 15 is connected directly to the output terminal 11, the terminal 9 to the output terminal 14 of the third DC amplifier 13 connected and the input terminal 12 of the drift storage circuit 17 via switch 15 with the Capacitor 16 is connected.

In addition, when the third DC amplifier 13 of the embodiment shown in Fig. 1, is that the terminals 12 and 14 are in an inverse phase relationship are, the output of the first DC amplifier 7 is connected to the input terminal 9 of the second DC amplifier 10 connected, while the output of the drift memory circuit I7 to the input terminal 8 of the second DC amplifier 10 is connected.

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As mentioned above, there will be a drift in the output voltage of the DC amplifier before amplification and the feedback displayed on the input of the DC amplifier, so that the drift, which in relation to the input of the DC amplifier is transformed, is compensated. Since accordingly a drift compensation according to the Invention in an economical manner and without affecting the wide band characteristics of the DC amplifier can be generated, this invention can be widely applied to analog-to-digital converters and oscilloscopes, etc. will.

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Claims (4)

- 11 PATENT CLAIMS ι Ij / DC amplifier circuit with an input terminal, an amplifier device coupled to this input terminal and an output terminal connected to this amplifier device, characterized by a first switch (2) between the input terminal (1) and the amplifier device, by the amplifier device forming elements, such as a first DC amplifier (7), which is connected to the output of the first switch (2) is connected, and a differential amplifier (1O), one input (8) of which is connected to the output of the first direct current amplifier (7), and through one Drift storage circuit (17) between the output of the differential amplifier (10) and the other input (9) of the differential amplifier (10) for a feedback of the output of the differential amplifier (10) when the first switch (2) is connected to ground, and for a continuous generation of a voltage acting like a feedback signal, which substantially equal to the drift voltages of the first direct current amplifier (7) and the differential amplifier (10) and transformed with respect to the input of the differential 109847/1706 - 12th amplifier (10) is. 2. DC amplifier circuit according to claim 1, characterized in that the drift storage circuit (17) consists of a second direct current amplifier (13) .einem second switch (15) »which is connected to the output of the second direct current amplifier (I3) and then switched on is when the first switch (2) is connected to "ground (3-5), while it is open when the first switch (2) connected to the input terminal (l) is (3 - 4), and consists of a capacitor (l6), which via the output of the second switch (15) and the ground (Pig, l) is switched. 3. DC amplifier circuit according to claim 1, characterized in that the drift storage circuit (17) consists of a second switch (15) which then is closed when the first switch (2) is grounded (3 - 5) »while it is open when the first Switch (2) is connected to the input terminal (l) (3-4), and a capacitor (l6), which is connected to the output of the second switch (15) and ground (Pig. 2) is switched. 109847/1706 4. DC amplifier circuit according to claim 1, characterized in that the drift storage circuit (17) consists of a second switch (15) which is closed when the first switch (2) is connected to ground (3 - 5) * while it is then open when
the first switch (2) at the input terminal (l) is (3-4) * made up of a capacitor (16) which is connected to the output of the second switch (15) and ground, and a second direct current amplifier (l ] 5), which is connected to the output of the second switch (15) (Fig. 3). 109847/1706