CS273396B1 - Connection of long time constant circuit - Google Patents

Abstract

The passive elements in the connection of the typical integrating link at best connected with the operational amplifier with the capacitive feedback are most often used for the integration of the measured signal. The integration time depends in these cases on the size of the resistance, capacity, and quality of the amplifier and therefore they limit it. According to the invention, the connection of the circuit removes these deficiencies. The amplification selection of the potentiometric amplifier causes either the decrease in the size of value of both the elements or increase of the time constant. The time constant is generally expressed by the relation <IMAGE>RC.It is <IMAGE> RC in the case of the connection according to the invention. And where A is the amplification of the potentiometric amplifier.<IMAGE>

Description

Connection of the long Saxon constant circuit (57) To integrate the measured signal, passive elements are most often used in the wiring of a typical integration salt at best in conjunction with an operational amplifier with capacitive feedback. The integration time in these cases depends on the resistance, capacitance, amplifier quality and is therefore limited. By connecting the circuit according to the invention, these drawbacks are eliminated. By selecting a potentiometric amplifier gain, either a decrease in the magnitude of the two elements or an increase in the Sas constant is obtained.

In general, the time constant is expressed as <£ 4 / RC. In the case of the circuitry according to the invention, it is µC. A where A is the potentiometric amplifier gain.

CS 273396 Bl

The invention relates to a circuit of a long Saxon constant to extend the integration time of the measured signal.

Passive RC cells or an integrated amplifier with capacitive feedback are most often used for signal integration. In this embodiment, too high time constants are usually not achieved, especially with a bipolar signal. The limiting factor is the magnitude of the values of both passive elements and the quality of the amplifier used and therefore the higher purchase costs.

These drawbacks are overcome by the circuit of the long Saxon constant according to the invention, which is based on the input terminal being connected via an input resistor to the inverting input of a normalization amplifier. Its non-inverting input is connected to the common terminal and the output to the first output terminal, while the second output terminal is connected via a comparative resistor to the common terminal and to the non-inverting input of the potentiometric amplifier. At the same time it is also connected via the feedback resistor to the inverting input of the normalization amplifier. The inverting input of the potentiometric amplifier is connected via a lower resistor to the output of the potentiometric amplifier, whose output is connected via a timing capacitor to the inverting input of the normalization amplifier.

The advantage of the circuitry according to the invention is that long time constants are achieved at normal resistance values and capacitance only by selecting the gain of the potentiometric amplifier. At the same time, the circuit is considerably more dimensional and less expensive.

The attached drawing shows an exemplary embodiment of a long time constant.

Input terminal 1 is connected via input resistor 2 ^to inverting input 41 of normalization amplifier 4, its non-inverting input 42 is connected to common terminal 2 and output to first output terminal 11. Second output terminal 12 is connected via comparing resistor 7 to common terminal At the same time, it is also connected via the feedback resistor 5 to the inverting input 41 of the normalization amplifier 4. The inverting input 61 of the potentiometric amplifier 6 is connected via a lower resistor 10 to a common terminal 2 and partly via an upper resistor 2. aa output of the potentiometric amplifier 6. Its output is connected via a timing capacitor 8 to the inverting input 41 of the normalization amplifier 4.

By applying the DC voltage to the input terminal 1 and the common terminal 2, a current occurs at the inverting input 41 of the normalization amplifier 4 via the input resistor 3, which causes the normalization amplifier output current 4 to flow to the first output terminal 11. the resistance 7 and the common terminal 2 close the output current. Passing the current through the resistor 7 creates a voltage drop. At the same time, the voltage at the comparative resistor 2 is amplified by a potentiometric amplifier 6, the gain of which is given by the ratio of the lower resistor 10 and the upper resistor 2 relative to each other. 6 induces the charging current flowing through the timer capacitor 8 to the inverting input 41 of the normalization amplifier 4. After charging of the timer capacitor 8 is complete, the output current stabilizes at the first output terminal 11.

The use of a long time constant circuit is assumed in measuring transducers of electrical quantities, in regulation and measuring technology.

CS 273396 Bl

Claims (1)

SUBJECT OF THE INVENTION A circuit of a long time constant, characterized in that the input terminal (1) is connected via an input resistor (3) to an inverting input (41) of the normalization amplifier (4), its non-inverting input (42) being connected to a common terminal (2). ) and output to the first output terminal (11), while the second output terminal (12) is connected via a comparing resistor (7) to a common terminal (2) and to a non-inverting input (62) of a potenoi amplifier (6). also connected via the feedback resistor (5) to the inverting input (41) of the normalization amplifier (4), the inverting input (6l) of the potenoi amplifier (6) is connected via the lower resistor (10) to the common terminal (2) and (9) to the output of a potentiometric amplifier (6), the output of which is connected via a timing capacitor (8) to the inverting input (41) of the normalization amplifier (4). 1 drawing CS 273396 Bl Her