SU1672583A1 - Correcting amplifier of scan signal of electron beam - Google Patents

Abstract

The invention relates to devices that scan the electron beam over the surface of the object under study, for example, in electron and X-ray scanning microscopy. The purpose of the invention is to improve the accuracy of the correction. The correction amplifier of the electron beam sweep signal contains an operational amplifier 1, an output amplifier 2, a deflection coil 3, a feedback circuit 4, a current sensor 5, a voltage source 6, valves 7 and 8, a drive 9. The goal is achieved by introducing the limit amplifier 10 , adder 11, controlled valve 12, additional amplifier 13, additional voltage source 14. 3 Il.

Description

1

The invention relates to devices that scan the electron beam over the surface of the object under study, for example, in electron and X-ray scanning microscopy.

The aim of the invention is to improve the accuracy of the correction.

Figure 1 shows the block diagram of the correction amplifier signal sweep of the electron beam; Fig. 2 illustrates the process of amplifying a sawtooth sweep current; FIG. 3 shows the electrical circuit of the corrective amplifier of the scanning signal of the electron beam.

The correction amplifier of the electron beam sweep signal contains (Fig. 1) operational amplifier 1, output amplifier 2, deflection coils 3, feedback circuit 4, current sensor 5, voltage source 6, two valves 7 and 8, accumulator 9, amplifier - limiter 10, adder 11, controlled valve 12, additional amplifier 13, additional voltage source 14.

The corrective booster signal of the electron beam sweep works as follows.

The negative feedback current is supplied from the current sensor 5 (resistor) through the feedback circuit 4, made, for example, on a resistor, to the input of operational amplifier 1, where it is summed with the input current iBx (t) (Fig. 2a). If the difference voltage (UA) at point A (Fig 2b) is small, which is true for a large gain of operational amplifier 1 and output amplifier 2, then the negative feedback current is proportional to the voltage on current sensor 5, and therefore to current ior (t) (FIG. 26). The negative feedback current is almost equal to the input current. THERE IS A DIFFERENT CURRENT ioT (t)

proportional to input iBx (t).

The differential voltage (1) d), amplified by the operational amplifier, is added in the adder 11 with the output voltage of the amplifier-limiter 10, which appears only when the absolute value of the differential voltage (UA) exceeds the threshold (Up) (Fig. 2c).

During the forward stroke of the sweep, the differential voltage is much less in absolute value of the threshold (Up) (Fig. 2B). The Yu limiter amplifier is closed and does not introduce static gain errors: shear and drift of the deflecting current (sweep). The controlled valve 12 is closed and the valve 7 is open. The output amplifier 2 is powered by the voltage (Un) of the voltage source 6, so the power consumption is small. During the return stroke, the differential voltage (UA) exceeds the threshold (Up), the limiting amplifier 10 opens and increases the differential voltage, bypassing the less high-speed operational amplifier 1 (especially when it is overloaded).

The differential voltage amplified by the limiting amplifier 10 is fed to the control equalizer of the controlled valve 12, and also to the input of the output amplifier 2 through the adder 11. The greater the error voltage (UA), the greater the voltage at the input of the controlled valve 12, by that

5, most of the voltage of the auxiliary voltage source 14 is applied to the power terminal B of the output amplifier 2. The valve 7 is closed by disconnecting the voltage source 6 from terminal B. In

The reverse voltage at the output of the output amplifier 2 (point C) can reach the value (Un + UnB. Fig. 2d).

Thus, a high voltage is supplied to the deflecting trunks of the carcass 3 through the output amplifier 2, which is necessary to accelerate the variation of the deflecting current through three abrupt changes in the input current.

Amp limiter 10, triggered

0 only at a sufficiently large value of the differential voltage (UA) and does not enter saturation in contrast to the operational amplifier 1. Therefore, an efficient control of the transient process of the negative feedback circuit during the reverse stroke (abrupt changes in the input current) and at the beginning of the forward sweep stroke.

The output voltage of the output amplifier 2 is still amplified by a non-inverting auxiliary amplifier 13 and is applied to the power supply terminal B. Therefore, in the absence of a significant input overload, when IVp | and controlled

5, the valve 12 is closed and the output amplifier 2 is maintained in an active (unsaturated) state. The negative feedback ring is not broken and there is no reloading when

0, the voltage of the power supply of the voltage source 6 (due to pulsations, etc.) is insufficient at some moment leads to an overload of the operational amplifier 1.

During the forward stroke and most

5 time return stroke valve 8 is closed. Therefore, to point B it is possible to connect for storage the drive 9 (a capacitor with a significant capacity), which increases the stability of the gain. This does not lead to an increase in the duration of the reverse stroke,

the deflecting coils 3 depending on their own distributed capacitance and the electron capacitances of the active elements of the output amplifier 2.

Since the output amplifier 2 is not included in the limitation, an increase in the duration of the return stroke is excluded. The fact that the limiting amplifier 10 by its input limits the error voltage at the threshold level (Up) also contributes to a decrease in the duration of the return stroke. This prevents excessive saturation of the operational amplifier 1 and its slowdown.

All this, in addition to the constantly acting negative feedback, not only additionally reduces the duration of the return stroke, but also increases the gain accuracy at the beginning of the forward sweep stroke.

Fig. 2c shows the differential voltage, proportional to the gain error in the traditional construction of scanning amplifiers, by a dash-dotted line. The limiting amplifier 10 (FIG. 3) consists of two amplifiers that react to a positive (transistors 15 and 16) and negative (transistors 17 and 18) differential voltage (V) at point A. Their output currents are summed with the output currents of operational amplifier 1 and with currents formed by transistors 19 and 20 in the emitter circuits of transistors 21 and 22. The potentials of the bases of transistors 21 and 22 are fixed with potentiometers 23 and 24.

The output voltages of the adder 11 of the transistors 21 and 22, necessary for controlling the push-pull output amplifier 2, are formed on the resistors 25 and 26. In the output amplifier stage 2, the bias voltage sources 27 and 28 are used. The output of the output amplifier stage (point C) is shunted by a diode 29, and the supply voltage to terminal B from the voltage source 6 is supplied through diode 30.

As an additional amplifier 13, a voltage follower is used on the transistor 31, to the input of which a voltage is applied through a bias circuit 32 and 33.

The control valve 12 is made of transistors 34 and 35 and a resistor 36. If the error voltage (negative) exceeds the absolute value of the threshold (FIG. 2b), transistors 17 and 18 open. Transistor 35 opens and its collector current flows through the resistor 36, causes the opening of the transistor 34.

The larger the mismatch, the more the transistor 34 opens and the greater the proportion of high voltage that goes to the power supply terminal B of the output amplifier stage.

The feedback voltage is formed on the resistor 37. This voltage causes a negative feedback current in the resistor 38. The capacitor 39 suppresses the high-frequency oscillations in the power supply circuit, ensuring the stability of the gain

Saving energy consumed from an additional voltage source 14 is achieved by using a multistage regulator (controlled valve) I-particular in a spin-up amplifier, I-particularly, a speed-controlled regulator functions as follows. Output (Uyo) limit amplifier is compared.

20 in the regulator with two thresholds (UPi) and (Up). (Dpi) (UD2) If (Iuo) (Up}, then the regulator is closed and the additional voltage source is disconnected from the terminal B (Fig. 3) If (Up-i) (Uyo) (Up2).

25 the key is connected to the voltage drop of the additional voltage source, for example, from the rectifier tap, which enters it.

If (uyn); (Up2). then to terminal B through

30 other key connects fully voltage to an additional voltage source

35

Formupa invention

A correction beam of the electron beam sweep signal, containing an operational amplifier, serially connected output amplifier, deflecting coils and a current sensor, also a feedback circuit, two valves, a drive and a voltage source, the feedback circuit being connected at one end connecting the deflecting coils and the current sensor 45 and the other end to the input of the operational amplifier, the positive output of the voltage source through the first gate is connected to the first power input of the output amplifier, the output which through

50, the second valve is connected to the first power input of the output amplifier, the negative terminal of the voltage source is connected to the second power input of the output amplifier, the first output of the drive is connected to

55 with the first power input of the output amplifier, and the second output of the accumulator is connected to the corresponding output of the current sensor and the common bus of the correction amplifier, characterized in that, in order to improve the accuracy of the correction,

The larger the mismatch, the more the transistor 34 opens and the greater the proportion of high voltage that goes to the power supply terminal B of the output amplifier stage.

The feedback voltage is generated across the resistor 37. This voltage causes a negative feedback current in the resistor 38. The capacitor 39 suppresses the high frequency oscillations in the power supply circuit, ensuring the stability of the gain

Saving the energy consumed from the additional voltage source 14 is achieved by using a multistage regulator (controlled valve) in the booster amplifier (I-particular), a speed regulator functions as follows. Output (Uyo) limit amplifier is compared.

0 in the controller with two thresholds (UPi) and (Up). (Dpi) (UD2) If (Iuo) (Up}, then the regulator is closed and the additional voltage source is disconnected from the terminal B (Fig. 3) If (Up-i) (Uyo) (Up2).

5 the key is connected to the voltage drop of the additional voltage source, for example, from the rectifier tap, which enters it.

If (uyn); (Up2). then to terminal B through

0 another key connects fully voltage to an additional voltage source.

35

Formupa invention

amplifier-limiter, controlled valve, additional amplifier, additional voltage source and adder, the input of the operational amplifier through the amplifier-limiter is connected to the first input of the adder and the control input of the controlled valve, the positive output of the additional voltage source is connected through a controlled

the valve with the first input of the output amplifier power, the negative terminal of the additional voltage source is connected to the input of the first valve, the output of the output amplifier is connected via an additional amplifier to the first input of the output amplifier, whose information input is connected to the output of the operational amplifier through the adder.

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Claims (1)

Claim An electronic beam sweep correction amplifier comprising an operational amplifier, an output amplifier connected in series, bias coils and a current sensor, as well as a feedback circuit, two valves, a drive and a voltage source, while the feedback circuit is connected at one end to the connection point of the bias coils and a current sensor and the other end to the input of the operational amplifier, the positive output of the voltage source through the first valve is connected to the first input of the output amplifier power, the output of which through the second valve it is connected to the first power input of the output amplifier, the negative terminal of the voltage source is connected to the second power input of the output amplifier, the first output of the drive is connected to the first power input of the output amplifier. and the second terminal of the drive is connected to the corresponding terminal of the current sensor and the common bus of the correction amplifier, characterized in that. in order to improve the accuracy of correction, an amplifier-limiter, a controlled valve, an additional amplifier, an additional voltage source and an adder are introduced, while the input of the operational amplifier is connected through the amplifier-limiter to the first input of the adder and the control input of a controlled valve, the positive output of an additional voltage source is connected through controlled valve with the first power input of the output amplifier, the negative terminal of the additional voltage source is connected to the input of the first valve, the output The output amplifier 5 is connected through an additional amplifier to the first power input of the output amplifier, the information input of which is connected to the output of the operational amplifier through an adder.