DD278042A3 - Voting procedure and equipment for capacity measuring bridges - Google Patents

Abstract

The field of application of the invention is the measurement of the smallest changes in capacitance by means of capacitance measuring bridges, above all the capacitance spectroscopy of semiconductors. According to the invention, after inserting the sample, the charge and the impedance of the preamplifier input circuit are first reduced via the first control voltage, then the sample circuit is adjusted in a conventional manner, then the charge of the preamplifier input circuit is raised again by means of the first control voltage and then by means of the second , applied to the capacitance diode control voltage, the resonant frequency of the preamplifier input circuit changed to achieve the full balance. In the inventive tuning device between the preamplifier input and ground, a controllable resistor and a capacitance diode are connected in parallel. figure

Description

For this 1 page drawing

Field of application of the invention

Field of application of the invention is the measurement of smallest capacity changes by means of capacitance measuring bridges, especially the capacitance spectroscopy of semiconductors. Special advantages have their application in the so-called. Scanning DLTS method.

Characteristic of the known state of the art

For measuring the smallest capacitance or capacitance changes with high sensitivity, various types of measuring bridges are specified and put to practical use. The high demands that the capacitance spectroscopy on semiconductors, arrangements of the principle described in DD-PS 202,764 are largely fair, in which applied to one side of the sample, an AC voltage and on the other hand, the change of the alternating current associated with a change of Probenleitwerkes is detected by the sample is such that the sample is part of a tuned to the measuring frequency resonant circuit and the input capacitance of the preamplifier circuit is supplemented with an inductance to the measuring frequency tuned second resonant circuit ("parallel resonant arrangement".) The object of the adjustment of these arrangements consists of two parts, on the one hand the adjustment of the sample capacity and the grain compensation of the loss component - ie the adjustment of the resonant circuit containing the sample to minimum RF voltage at the preamplifier and on the other hand from the fine balance of the second resonant circuit at the preamplifier Ngang, which affects the sensitivity of the arrangement and also the phase position of the RF signal. Although the tuning state of this circuit is due geometriebingtingt different stray capacitances of the sample terminals to ground, so that a fine balance is required.

When changing samples, the sample circuit should be finely tuned to the capacitance and the loss content of the new sample, and then to the preamplifier input circuit, starting from the roughly adjusted in the preamplifier input circuit at the beginning of the measurements. In the usual Abdtimmverfahren affects adversely that due to the (especially at medium and large sample capacity) very sharply matched balance of the RF signal initially after the sample change - that is not even calibrated Prüfkreis- virtually the entire RF voltage at the preamplifier input and overrides this. This must be countered by reducing the RF voltage and / or the RF gain, this is the first requirement to be able to adjust the sample circuit.

The Hauotproblem in solving this subtask, however, is the existing in the previous parallel resonant bridge arrangements extensive independence of the RF signal from the balance state in the unbalanced state. In order to find the proximity of the tuning minimum, so far an intuitive approach is needed.

When the sample circuit is substantially balanced, the preamplifier input circuit is balanced to the maximum RF amplitude and phase, respectively, which is done in the prior art by manually adjusting the inductance at the preamplifier input to ground.

This procedure is very time consuming and user-friendly and requires a lot of experimental experience. In addition, with special DLTS variants such as the scanning DLTS method, the measuring arrangement is not easily accessible, a manual vote would - if ever feasible - here require an unreasonable design effort.

Object of the invention

The aim of the invention is to provide a tuning method as well as its realization serving arrangement for capacitance bridges in parallel resonant arrangement, which allow a simple, largely error-free and fast operation and allow the use of the measuring bridge even in measurement tasks where it is not mechanically accessible.

Explanation of the essence of the invention

The invention has for its object to develop a tuning method and its realization serving arrangement for capacitance measuring bridges in parallel resonant arrangement, which contain no mechanical elements, the adjustment for a one-to-one dependent on the adjustment state signal and without interim change of the RF voltage and / or Reinforcement of the bridge should allow.

According to the invention, the object is achieved by providing a method and an arrangement which are distinguished by electronic influencing of both the frequency and the quality and thus sensitivity of the preamplifier input circuit, the arrangement according to the invention comprising a parallel connection of a controllable resistor and a capacitance diode Represents preamplifier input and ground.

The method is characterized in that initially reduced by the control voltage applied to the first control voltage, the quality and thus the impedance of the preamplifier input circuit, then adjusted in a conventional manner, the sample circuit, then increased by the first control voltage, the quality of the preamplifier input circuit again and then by means of second, applied to the capacitance diode control voltage, the resonance frequency of the preamplifier input circuit is changed until the full balance.

Reducing the quality of the preamplifier input circuit substantially reduces the sharpness of the trim minimum, thereby eliminating the main problem of sample matching, namely, the substantial independence of the RF signal from the trim state outside of the exact trim.

The arrangement is thus beyond the solution of the above-mentioned task suitable to set a reduced sensitivity of the measuring device in a simple and fast way - for example, for the measurement of samples of high capacitance change and thus to expand the scope of the measuring bridge.

As a controllable resistor, an FET can be selected; In an advantageous embodiment of the solution according to the invention, it is the same FET de in standard measuring bridges of the type described fulfills the function during and shortly after the application of voltage pulses to the sample short the preamplifier input, and there is otherwise out of service.

embodiment

In the figure, an expedient realization of the arrangement according to the invention is shown. The RF transformer 2 is designed to achieve a strong coupling as a quad-balun transformer with parallel, connected to the Hr generator 1 primary windings and separate secondary windings. The bias voltage for the sample 3 is supplied via an impedance converter 4, which implements the required RF short-circuit on the output side. Since no steep-flanked pulses have to be applied to the capacitance diode 5, the RF short-circuit is implemented there by a capacitor 6. The corresponding connection for the circular inductance 7 is directly connected to ground. The secondary winding for compensation of the loss component is so beschältet that via an electronically controllable resistor 8, a 180 ° phase-shifted RF current parallel to the sample circuit to the common terminal, the RF preamplifier 9 is supplied. Its input capacitance and stray capacitances to ground are compensated by a second inductor 10.

According to the invention, the field-effect transistor 11 controlled by the first control voltage U4 and the capacitance diode 12 connected to the second control voltage U5 are located between the preamplifier input and the ground. The connection of the control voltage U5 is short-circuited in the usual way with a capacitor 13 to ground HF-moderately. The control voltage U 4 is selected during and a gewissa time after a pulse of the sample bias voltage U1 in a known manner so that virtually a short circuit occurs at the preamplifier. During the DLTS measurement phase after the pulse and during the tuning process U 4 is set according to the invention so that the desired for the respective measurement or tuning task sensitivity of the device is achieved. Is U 4 chosen so that the field effect transistor 11 is high impedance and the Vorversiärkungskreise has a high quality, can be done according to the invention via the tuning voltage U 5, an optimization of the sensitivity of the arrangement or the phase position of the signal.

Claims (4)

1. tuning method for capacitance measuring bridges, wherein the sample is part of a tuned to the measuring frequency resonant circuit and the input capacitance of the preamplifier circuit is supplemented with an inductance matched to the measuring frequency, lying between preamplifier input and ground resonant circuit, characterized in that after inserting the sample first reduced via the voltage applied to the controllable resistor first control voltage cie quality and thus the impedance of the preamplifier input circuit, then adjusted in a conventional manner, the sample circuit, then increased by the first Steuparfnung the quality of the preamplifier input circuit again and then by means of the second, applied to the capacitance diode control voltage the resonance frequency of the preamplifier input circuit is changed until the complete adjustment is achieved. 2. Abstimmeinrichtung for capacitance measuring bridges, in which the sample is part of a tuned to the Meiifrequenz resonant circuit and the input capacitance of the preamplifier circuit is supplemented with an inductance matched to the measuring frequency, lying between preamplifier input and ground resonant circuit, characterized in that between preamplifier input and ground a controllable resistor and a varactor diode are connected in parallel. 3. Tuning device according to claim 2, characterized in that the controllable resistor is a FET. 4. Tuning device according to claim 3, characterized in that the controllable resistor is that FET, realized in conventional bridges of the type described, the short circuit of the preamplifier input immediately after applying a bias pulse to the sample.