SU1026063A1 - Ac digital automatic extremum bridge balancing method - Google Patents

Abstract

1. METHOD FOR EQUIPPING THE DIGITAL AUTOMATIC EXTREME BRIDGES OF THE AC CURRENT by discretely adjustable parameters, in which small jump-like changes in the corresponding parameter of the bridge measuring circuit and in accordance with the amplitude of the output voltage amplitude of this circuit produce positive and negative negative symptoms of the negatives. , and the adjustment of the balancing parameter in the direction of equilibrium is carried out only in the absence of positive increments the amplitudes of the output voltage of the bridge measuring circuit, so that in order to simplify the circuit of the devices while increasing their speed, the working and trial (modulation) steps on all decades (tetrad), except the youngest one is combined and executed at the same time, and their value is always chosen equal to twice the discreteness of the adjustment of the balancing parameter on a given decade (tetrad), while in the absence of positive and negative pulsed regulating influences The doubled working step made is left unchanged and the next step is carried out in the same direction, with the appearance of a positive impulse control effect produced | changing the direction of adjustment by equalizing the parameter and making one return step equal to twice the discrete value of the adjustment of this parameter on this decade. (tetrade), with the disappearance of the negative and the absence of positive impulse regulators (their effects also change the direction of adjustment of the balancing parameter, and the return step is chosen equal to a single value of the discreteness of adjustment of this parameter on this tetrad (decade).

Description

2. The method according to claim 1, characterized in that the determination of the partial minimum of the amplitude of the output voltage of the bridge measuring circuit and the transition to equilibration in the next decade (tetrad) or

according to another parameter, it is carried out immediately after performing a single, as well as a double return step, if at least one negative impulse regulating effect was formed in front of it.

The invention relates to electrical measuring technology and is intended for use in digital AC bridges measuring complex resistivity and conductivity. Digital automatic extremal bridges are known for determining complex resistances and conductances in the rock and frequency range and ratings. Such devices are automatically balanced using pulsed controlled actions, formed by small test spasmodic changes, a balancing parameter (modulation steps) and the subsequent selection of the increments of the output voltage amplitude of the measuring circuit bridge, the test results from the above test changes. pulsing regulating actions that cause discrete changes in the equilibrium parameter towards the equilibrium of the device (working steps) are produced by the presence of negative modulation increments of the output voltage amplitude of the measuring circuit, and the determination of private minima and changing the direction of adjustment to the balance of each parameter are carried out by the absence of these negative increments. At the same time, in order to achieve the maximum accuracy of balancing, the working and modulation steps are chosen equal to 1. The disadvantage of the dacha method is that when using it, there is no sufficient noise immunity of devices in the equilibrium zone. The closest in technical essence to the present invention is a method of balancing digital modulation bridges of alternating current, according to which the formation of pulsed regulating actions causing the working steps of the balancing parameter is performed in the absence of positive modulation increments. The amplitudes of the output voltage of the measuring circuit and the determination private minima for each decade of the digital bridge as well. as well as changing the direction of the adjustment of the balancing parameter {balance reversal), the implementation They are made in the presence of positive modulation increments of this gilplita. In this case, the modular steps choose twice as large as the absolute value of the corresponding working steps 23. A disadvantage of this method of balancing digital AC bridges is the complexity of the operation algorithm and the use of instrumentation and understanding: the speed of implementation of the MS street implications and the presence of modulators for each decade of both balancing parameters. The purpose of the invention is to simplify the layout of devices with an improved increase in their speed. This goal is achieved in that, according to the method of balancing digital automatic extreme bridges, neipeMeHHoro, over a discretely adjustable pair; meters, in which small jump-like changes are made in the corresponding parameter of the bridge measuring circuit and in accordance with the sign of the increment amplitude; output; (voltage of this circuit is formed by positive or negative impulses regulating the impact, and adjustment of the balance parameter in the direction of equilibrium can be realized only in the absence of positive increments of the amplitude of the output voltage of the As-test measuring circuit, pa6o4He and test (modular) gains of modulus) pa6o4He and test (modular) voltage all decades (tetradas) except the youngest, combine and execute simultaneously / and the value of their Bcetvi; a Choose equal to twice the discrete value of adjustment of the balancing parameter per data decad tetrade), while in the absence of a positive and negative impulse from the regulating influences, the double working step made is left unchanged, and the next same step is carried out in the same direction, when a positive pulmonary regulator appears, the adjustment is reversed equalizing the parameter and taking one return step equal to twice the increment of the adjustment on this decade (tetrad), if the negative disappears and there is no positively regulates the pulse also produces effects x t change direction adjustment equation (yuvoshivagatsego parameter and vozvratnyy- step is selected to be the identity of the discrete adjustment of pargdaetra on this tetrad (decade).

Determination of the partial minimum of the amplitude of the output voltage of the measuring bridge circuit and the transition to equilibration in the next decade. , (tetrade) or on a steep pad, the meter is always produced immediately after a single as well as a double return step is discharged, if at least one negative impulse control action was formed in front of it.

FIG. Figure 1 shows a simplified bridge diagram with adjustment of only one parameter, illustrating an example implementation of the proposed balancing method; in fig. 2 - balancing graphics.

The device contains a bridge measurement circuit 1, an extremum detector 2 a clock generator 3, a reversible counter 4, a reverse trigger 5, a decade switching block, a pulse delay element 7 by one clock, a logical element OR 8 summation logic elements 9, 10 and 11 , logical elements And 12; 13 and 14. matches with the inversion of one of the inputs.

The bridge measuring circuit 1 serves to measure the impedance and is balanced by means of discrete control of one of its parameters. This control is carried out by reversing 4 with counter 4, which has two inputs. When pulses are fed to the first input, the counting is done by twos, and when pulses are fed to the second input, by units i The counting direction of the reversible: Counter 4 and, consequently, the direction of adjustment of the url & Versa. Block 6 of the decade switch selects the balance decade by controlling the reversible counter 4. Extre1 detector. 2 has two outputs and, in accordance with the increment sign of the amplitude of the output voltage {bridge bridge, measuring circuit 1, forms a positive or negative impulses. The working rhythm for the whole bridge is set by the clock generator 3, it also controls the logic elements 9 - 12. Control pulse delay element 7 Also, the clock generator 3, it delays the negative pulses from the extremum detector 2, one clock. The currently generated negative pulse blocks the logic element 13, and the negative pulse delayed by element 7 does not pass through the logic element 13. The output of the logic element 13 appears delayed. In the previous cycle, the pulse only when there is no subsequent blocking negative pulse, i.e. . at the termination of the arrival of negative impulses from the extremum detector 2. The output of element 13 is connected to the IMHO input of elements 9 and 14 ,. Element 9 transmits a pulse from the clock generator 3 to the switching unit 6 for decades only if there is a pulse at the output of element 13. Pulse from element 13 passes through element 14 only in the absence of a positive pulse at the output of extremum detector 2. Element 14 output is connected to summation logic element 8 logic elements 10 and 12. IF a pulse appears at the output of logic element 14, then .. it blocks-: the pulse passes through element 12 and opens element 10. 5 of the reverse is controlled by a logic element 11 Nij. and it works only if the output of the logic element 8 summation / according to the Wits pulse, i.e. at the occurrence of a positive pulse at the output of the extremum detector 2 or at the termination of the formation of negative pulses by the extremum detector 2.

The equilibrium of the bridge according to the proposed method occurs as follows.

Let measuring circuit 1 be out of equilibrium by several steps, the state of flip-flop 5 corresponds to adjusting the equilibrium of this parameter in the direction of equilibrium, and Positive negative pulses, there is no output of extremum detector 2 (the beginning of balancing. In this case, element There is no pulse delay and there will be no impulses at the output of the clock player 3 at the output of the logic elements 13 and 14. The logic element 10 will be locked and the logic element 12 will coincide with nversiey open inlet through it with a clock pulse generator 3 is supplied to a first input reverb-intensity counter 4 which dit account productivity twos:. aside is: Ves working step is carried out

on the balancing parameter equal to twice the value of its adjustment discreteness. The extremum detector 2 will then form a negative pulse, which will be recorded in the pulse delay element 7. When the clock generator 3 is triggered, the next double loop will be made in the direction of equilibrium, since the negative pulse from the extremum detector 2 will block the logic element 13 and the pulse from the pulse delay element 7 will not enter its output. This will happen until equilibrium is reached in this decade (tetrad). If, when the equilibrium at the output of the extremum detector 2 reaches a positive pulse, it closes the logic element. 14 To pass pulses from the logic element 13, pass through the summation element 8 and open the logic element of the 11 coincidences to pass pulses from the clock generator 3 to the trigger 5 of the reverse. The reverse trigger will work, and in the next cycle the reversible counter 4 will produce a double return step. After that, the logic element 9 receives a pulse from the clock generator 3, and since this element is opened by the Pulse from the output of the logic element 12, a pulse will pass to the switching unit 6 of the decades and cause the transition of bridge circuit 1 to equilibration in the next lower decade. If, however, when the equilibrium is reached at this decade, neither the positive nor the negative impulses are formed by the extremum detector 2, then the impulse from the output of delay element 7 will pass through logic element 13 and enter the input of logic elements 9 and 14. Since element 14 will be open, this impulse will pass to the logical element. 8 Summation, opens element 11, and clock generator 3 will transfer trigger 5, reverse to the opposite state. In addition, the pulse from the output of the element 14 will block the passage of pulses through the logic element 12 and open the element 10. The pulse from the clock generator 3 through the element 10 will pass to the input of the reversible counter 4, and a return step equal to the unit of the discrete adjustment of the balancing parameter will be performed decade. Since, as in the previous case, the pulse from the output of element 13 will open the logical element 9 of coincidence, the pulse from the clock generator 3 will trigger the unit 6 to switch the decades

and pavement chain 1 will also be triggered on the next lower decade. .

FIG. 2.1 is a graph showing the balancing of the bridge in case of imbalance of the measuring circuit by an odd number of steps in a discrete adjustment of the balancing parameter P, the value of which is plotted along the abscissa axis. The ordinate axis represents the amplitude of the output voltage of the bridge measuring circuit UQ. From the state characterized by the point O, the bridge passes sequentially from the state -6, cus and y / s. When going from the state otc to the state -4 /, a positive trigger occurs at the output of the extremum detector and doubled reverse step from state to state E1C. Balancing is complete. The transition is made to the next decade.

FIG. 2.2 shows a graph of the balancing bridge in case of imbalance by an even number of discrete steps for adjusting the balance parameter P. The balancing process is performed in the same way as in the previous case. However, since during the transition from the State (the J-to the EY state does not form a positive impulse, the return step will be equal only to the unit of discreteness of the adjustment of the balancing parameter p and the bridge will go from the YaC state to the e state.

Digital bridges (kst.remalnye bridges for measuring complex resistances are widely used in metrological laboratories, in monitoring and measuring the electrical parameters of products of the radio engineering and electrical industry, in measuring non-electrical quantities (shkroperemeshcheni, angular displacement, pressure, force level of liquid substances, etc.) with the help of complex electrical transducers.Obviously, the simplification of such devices will lead to a decrease in their cost and will give a significant economic effect The proposed Balancing Method MOCTOJB allows refusing the use of complex modulators connected to each decade of the measuring circuit of the bridge (for five decades according to each parameter of such modulators nine), slightly increasing the number of simple reliable logic elements used. , the speed of the instruments increases, as there is no need for the implementation of modulation steps.

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Claims (2)

1. METHOD FOR BALANCING DIGITAL AUTOMATIC EXTREME AC BRIDGES by discretely adjustable parameters, in which. Small stepwise changes of the corresponding parameter of the bridge measuring circuit are made and, in accordance with the sign of the increment in the amplitude of the output voltage of this circuit, form positive and negative pulse regulating regulatory actions, and in the direction of equilibrium, they carry out only in the absence of positive increments the amplitude The output voltage * of the bridge measuring circuit, distinguished by the fact that, in order to simplify the circuit · devices while increasing their speed, working and trial (modulation) steps on all decades (tetrads), except the youngest, combine and perform at the same time, and their value is always chosen equal to twice the value of the discreteness of adjustment of the balancing parameter in a given decade (tetrad), while in the absence of positive and the presence of negative impulse regulatory actions made twice This working step is left unchanged and the next same step is taken in the same direction, when a positive impulse control action appears, they change the direction of adjustment of the balancing parameter and make “one return step equal to twice the discreteness of adjustment of this parameter in this decade (notebook) ), with the disappearance of the negative and the absence of positive pulsed regulatory actions also produce a change in the direction of adjustment balancing nd parameter, and the return step is selected to be equal to the unit value of a discrete adjustment of this parameter on this tetrad (decade). SU-. 1026063 2. The method of Pop. 1, characterized in that the determination of the partial minimum of the amplitude of the output voltage of the bridge measuring circuit and the transition to balancing in the next decade (tetrad) or in another parameter is carried out immediately after performing a single, as well as double return step, if at least one negative impulse regulatory action was formed in front of it. as well as a change in the direction of adjustment of the balancing parameter верс (balancing reverse), they are carried out by the presence of positive modulation 5 ’incrementations of this amplitude. In this case, the modulation steps are chosen to be twice as large in absolute value / value of the corresponding work steps £ 2]. The disadvantage of this method of balancing digital AC bridges is the complexity of the operation algorithm and instrument circuits and the reduced speed due to the need for separate implementation of modulation effects. and the presence of modulators in each decade of both balancing parameters,. The purpose of the invention is to simplify the circuitry of devices while improving their performance.