DE1039130B - Electron beam oscilloscope - Google Patents

Description

Electron Beam Oscilloscope Presently, that invention relates to Schriel on an electron beam oscilloscope for measuring purposes, in which de measuring direction are specially trained for time and tension. Further additional devices in different combinations result in a particularly universal applicability Device.

In previous designs of cathode ray oscilloscopes, primarily placed emphasis on purely visual observation. In more recent times, however, is the aim is to ensure that the processes being observed can be calibrated. In particular, they are newer Constructions known in which partially both a calibration of the time base as well as the Y deflection voltage is sought.

The oscilloscope described here builds on this principle of Verifiability further au.s. Likewise, there is a tendency to use of DC amplifiers and DC coupled pulse circuitry perfected and specially made usable for verifiability.

The use of direct current amplifiers has only recently become more common and direct current couplings have the advantage of an absolute verifiability of a line drawn on the cathode ray tube with respect to a voltage level to be measured Avoidance of low-frequency transients caused by RC coupling elements arise in AC amplifiers.

The principle of the differential amplifier has so far mainly been Only found in the low frequency range and is therefore mostly only used in oscilloscopes to be found with a small bandwidth (some 100 kH). Electron switches were at Oscillographs for higher bandwidths always as replaceable resin built-in units or attachment units supplied. These electronic switches are equipped with an additional The same preamplifier combines the same at a switching level of a few volts work up to a few tens of volts.

Various devices have appeared on the market, called those for electronic switches and differential amplifiers additional facilities such as Attachments or separate plug-in units are provided.

A voltage calibration is mostly used with previous oscilloscopes known by switching one of the existing input channels to a square wave Voltage (sometimes also sine wave) made, whereby it is particularly disadvantageous, that the actual measuring process is interrupted during the voltage calibration got to. The voltage calibration is carried out in this way. that the sensitivity of the device is calibrated in advance. so that after an adjustment of an amplitude fine controller gives a defined sensitivity in volts / mm. The measuring voltage can then be Calculate from the deflection multiplied by the division ratio of the input divider.

The disadvantage of this method is that the once calibrated Sensitivity in the course of operation both due to aging of the tubes as well can change due to mains voltage fluctuations, so that the accuracy of the voltage measurement is in question.

These parts are needed in the new electron beam oscilloscope avoided its Y amplifier according to the invention by the combination of the following features characterized: a) a circuit arrangement. in which a Y differential amplifier cooperates with an electronic switch known per se; b) a circuit arrangement for voltage measurement with the help of the electronic switch, consisting of a adjustable calibration voltage source, which can be either positive or negative towards zero Outputs calibration voltage, and a voltmeter to display the calibration voltage and a Changeover switch, which this calibration voltage optionally a channel of the electronic switch supplies as displacement voltage; c) a circuit arrangement with a changeover switch for voltage calibration with the help of the Y differential amplifier, in which the changeover switch is designed that the calibration voltage optionally an input of the differential amplifier as a shift voltage is fed; d) a circuit arrangement to compensate for harmful capacitances, in which a network is provided in the differential amplifier, which like a Capacity with a negative sign acts and which from an additional amplifier stage consists, which on the output side as catho- the amplifier works, whose Anode circles additionally with a cross-coupling with the grid on the input side are connected. and their negative capacitive reactive current due to the capacitive load of the cathode circuit is determined.

The structure and mode of operation of such an oscilloscope are explained in more detail below with reference to the figures.

Fig. La shows an electron switch with a Y amplifier; Fig. lb shows another embodiment of a Y-amplifier; Fig. 2 shows the control part to the electronic switch.

The Y amplifier according to FIG. 1 a consists of tubes 1 to 6 and is consistently designed as a push-pull amplifier. The tube 1 acts as a cathode amplifier, a variable resistor 15 is provided for Y-position control. The misalignment tension is due to the asymmetry of the current flows through the two halves of the tube 1 and the resulting shift in the grid prestress. The tube 2 works as a normal push-pull stage with an asymmetrical input voltage. A negative feedback regulator 14, which is arranged between the two cathodes of the tube 2. enables the amplitude fine control. The phase reversal of the tube 2 is through the Actuation of the negative feedback regulator 14 is not significantly affected because the two Cathode resistances 16 and 17 are large compared to the resistance of the regulator 14. A voltage divider ferrule supports the anode voltage of the tube 2, so that a direct galvanic coupling to the grid of the tube 3 can take place. This kind the coupling corresponds to the usual one known from direct current amplifiers. The tube 3 is in turn cathode-coupled by a cathode resistor 18. so that remaining asymmetries. which possibly exist in the anode circuit of the tube 2 can be canceled. Cross-coupling by means of two capacitors 19 and 20 enables compensation for the grid anode capacitance of the triodes. These This is the only reason why cross-coupling is not provided for in stage 2. because the same is fed by two cathode amplifiers, which are sufficiently low-resistance to the to control capacitive load there.

The aforementioned adjustable capacitors 19 and 20 also make it possible In addition to compensating for the grid anode capacitance, undistorting the Frequency response of the stage, which is an inductive equalization of the anode circuit is roughly equivalent. There becomes an improvement factor of about with this arrangement 1.5 achieved.

In the anode circuit of tube stage 3 there is a deeper pre-equalization Frequencies and the direct current component for the subsequent splitter coupling instead.

This pre-equalization is made possible by the additional external resistors 21 and scored 22. which are bridged by a capacitor 23. The condenser 23, which is thought to consist of two capacitances arranged symmetrically with respect to earth can be, is united in one link according to an embodiment of the invention, so that there is only a single effective time constant for the two anode circuits can result. The following divisor. consisting of an RC combination 24 and a resistor 25 hzw. a second RC combination 26 and a resistor 27, is dimensioned in such a way that it has a transmission factor of approximately "one" for high frequencies supplies. For low frequencies and the equal current component, on the other hand, is such available according to its resistance divider ratio. The dividing ratios and time constants of the pre-emphasis and the coupling splitter are dimensioned so that one The frequency response of the two series-connected elements is canceled.

The tube stage 4 at the taps of the coupling splitter is used as a cathode amplifier executed. That is the reason for this. that a cathode amplifier is proportionate can easily be dimensioned so that there is no grid current insert in its modulation range results. which would inadmissibly stress the coupled device. This is the ability to override of the amplifier at this point ensures what an oscilloscope amplifier is not insignificant.

The subsequent tube stage 5 is already a power stage, which is why two tubes are connected in parallel. They are in the cathode circle of these tubes two separate cathode resistors 28 and 29, which are connected by a negative feedback resistor 30, are bridged in an a-shape. This resistor 30 in turn has one of a Capacitor 31 and a coil32 existing bridging on which the negative feedback effect of the resistor 30 for high frequencies aufhel t. With the help of this high increase the frequency response of the anode circuit of the tubes 5 is compensated as far as possible. the External resistances 33, 34 of this tube stage are with regard to the properties of the amplifier relative to the dynamic range at medium frequencies sized large. Because the harmful capacities through the subsequent cathode amplifier stage are relatively small, the relatively large value of the resistors can also be derived from this 33. 34 justify.

The subsequent tube stage 6 makes use of a double Use. This is where the anodes and cathodes are cross-linked Output stage before, which is made by means of two capacitors 35 and 36. These Circuit arrangement is based on what is known as a "cathode circuit" Arrangement, which both in their anode circuit and in their cathode circuit has the same resistances. Assuming that these resistances are equal and the push-pull operation with two such circuits each result in two related ones Equipotential points 37 and 38 or 39 and 40. These equipotential points for low Frequencies can be connected with capacitors at will. The special one The effect at this point is based on the fact that in the capacitively loaded output circuits an anode current and a cathode current come into effect, whereby the Effect of this tube is doubled in terms of performance. The dynamic range at given harmful capacitance is therefore twice as large as that in this circuit a simple cathode amplifier. At the same time there is still a reduction the differential output impedance z to half the value, which increases the cutoff frequency increased to twice that without taking into account the dynamic range. this in turn brings a further improvement in the compensation effect of the cathode amplifier with regard to its input grid cathode capacitance, which means greater external resistances 33 34 of the previous stage allows.

In the embodiment of the Y amplifier shown in Fig. Lb, which in the last tube stage acting forward from a circuit for generating one makes use of negative capacity. the first tube of the Y-amplifier works with it the input terminals 41 42 on a cathode-doubled tubular stage 43 which in in each case a symmetrical one with both symmetrical and asymmetrical input voltage Outputs output signal to the two push-pull channels. The cathode coupling takes place via a common cathode resistor 44.

The anode circuit contains two delay elements 45 and 46 which act on a downstream tube stage 47. The amplitude control (regular gain) takes place here in the second amplifier stage 47 again through a negative feedback resistor 48 in the manner already described. The same applies to the compensation of the grid anode capacitance performed by two cross-coupled capacitors 19 and 20. Likewise the splitter coupling with pre-equalization with switching elements 21 to 27. The tube stage 49 corresponds in its effect exactly to that of the tube stage 5 from FIG. 1 a.

Trimmer capacitors 50 and 51 are in turn used to compensate for the due to the large external resistances considerable dynamic grid anode capacity, while switching elements 30 and 31 again function as the frequency-dependent negative feedback exercise. A tube stage 50 shows a special circuit for generating a negative capacitance, which is the damaging capacitance in the anode circuits of the Tube stage 49 compensated. This tube stage 50 acts on the output side in turn as Cathode amplifier on plates Yp and YN of the oscilloscope tube. The harmful ones Capacities of this circuit cause one in the anode circuits of these tubes 50 Reactive current, which is equal to the reactive current du.roh the harmful capacities of the plates Yp and YN by a further cross-coupling by means of capacitors 51 and 52, these reactive currents are fed back to the anode circuits of the tubes 49. Since these reactive currents obey exactly the function of a capacitance, due to the fact that they are in phase opposition but are directed in the opposite direction to the coupling. are these capable of the Effect of a harmful capacity in the anode circles of the tubes 49 exactly compensate. Only the internal resistance of the output of the cathode amplifier sets here 50 a limit which precedes the harmful capacities on the plates Yp and YN appears.

This increases the reactive current at high frequencies set a limit. whereby the compensating effect of the circuit on a frequency range is limited, which is below the cutoff frequency of the output circuit of the cathode amplifier lies.

It is of particular importance in this circuit that the number those stages in which a jump in direct current potential must be overcome can be reduced because the single gain of a stage, e.g. B. Level 49, higher values achieved. This is particularly the case with the circuit arrangement according to FIG. 1 b by means of the stage 50 the case, because here by the compensation of the harmful Capacities in the anode circuit of the tubes 49 considerably greater external resistances than can be used so far.

Likewise, the effect of compensating for the grid anodecapacitance of the tubes 49 by the capacitors 51 and 52 further improved because the Cutoff frequency in the anode circuit of the tubes 49 correspondingly high fails and thus the compensation can be carried out in almost pure phases.

The electron switch is divided into according to FIGS. La and lb Tube stages 7, 8, 9 and 10. The actual switch tube of the electron switch is the tube 8, a double cathode amplifier with common output and common I <: athode resistance 60. This cathode amplifier is controlled by a control voltage 13 which is made straight again via the tube 7. reciprocally controlled, so that alternately tube system 8 1 or 8 II is made conductive. Provided the roof tension of the two control signals at the grids 8 I and 8II are the same, the two commute Tube systems around a balance point, so that in each case after switching sets the same cathode voltage at the cathode of the tube 8 again. The positive ones Roof lines of the two switch voltages can be determined by regulators 61 and 62 move individually so that two separate, superimposed Have zero lines mapped. The input voltage is applied via two tubes 10 the grid of a double diode 9 which has two resistor-capacitor combinations 63 and 64 act on the grid of the double triode 8. Takes place on these two grids hence a superimposition of the switching voltage with the input signals, where alternately the input signal from 8 I and from 8 II on the output 65 of the electron switch got. At this output 65 is. to the input sensitivity of the Y-amplifier adapt. a divider 69 is provided, its output voltage to the one input terminal 42 of the Y-amplifier works. Because of the inevitable capacities between the grids and the cathodes of the tube 8 results in a crosstalk, which is caused by a second Time constant member 65, 66 is simulated.

The crosstalk voltage obtained in this way is used to compensate for the other input terminal 41 of the Y amplifier switched. its differential effect the disturbance in the anode circuit of the tubes 43 disappears.

To switch from electronic switch operation to differential amplifier operation or vice versa, a changeover switch 67 is actuated, which is also used for the Calibration voltage with a system 68 makes a corresponding switchover, which for the electron switch by the divider 69 becomes necessary.

The voltage calibration, which is only shown in FIG. 1 a, takes place by a voltmeter 70 with a variable resistor 71 which optionally one against Can emit zero positive or negative calibration voltage. The voltmeter 70 points accordingly a zero point in the central position. The calibration voltage can be achieved by means of a connection at Y-divider II (number 11) to Y-input II (behind the divider) in place of one second input signal can be switched on.

This type of voltage calibration during operation relates to therefore only on single-channel operation both with the differential amplifier and with the electronic switch. When using the differential amplifier, this variable calibration voltage is expressed in a 1-position shift of the entire image. where the displacement stress can be read on the voltmeter. When reading, the selected division ratio is to note. in order to avoid incorrect readings of the order of magnitude.

When using the electron switch, a second level line is created in the picture, which is also in their location can be shifted. while the actual image to be examined is fixed in its position. The tension level this level line is also on the voltmeter 70, which is next to the cathode ray tube is arranged on the front panel of the device, readable. In any case, it has Type of voltage calibration has the advantage that one of the two input channels for the actual measuring process is kept free during voltage measurement, so that for the calibration switching the reed is not required. Because it is a kind of compensation procedure the measuring accuracy depends only on the accuracy of the voltmeter from, possibly on the line thickness of the cathode ray tube. but not from any Non-linearities and amplification fluctuations in the Y-amplifier.

The process is therefore not only particularly practical and simple during operation, but also much more precisely.

The control part for the electron switch shown in FIG. 2 consists. from tubes 80, 81 and 82. The input terminal H is connected to the light control line of the Time numeric unit connected and supplies a square-wave control voltage with the duration of the tipping process. This tension is amplified by the tube 80 and limits and controls a flip-flop 81.

The circuit arrangement is such that the flip-flop circuit 81 reversed with the trailing edge of the time deflection (at the beginning of the tilt return) will. The flip-flop circuit 81 therefore runs tilt-synchronously, divides the tilt frequency binary and switches in the darkened tilt return. The switching time of the flip-flop circuit and the electron switch is therefore not critical since several Fs are available for this stand. The moment of switchover is inevitably open with the tilt return darkens the screen. As a result, the switchover, which is disturbing in the picture, can be blanked out be that optically for the viewer the function of a real two-beam oscillograph results.

The tube 82 has the task. that of the flip-flop circuit 81 to convert the supplied rectangular voltage into an exactly rectangular voltage.

Any remaining interference on control signal 13 (Switching voltage) are eliminated in the tube 7 (Fig. La. 1 b). This particular one Care is required in clearing the switching voltage of interference. because they with its positive roof line forms the zero line for the Y deflection and any disturbance the switching voltage would appear in the picture.

It should also be pointed out. that between the tubes 81. 82 pure DC coupling exists. what the straightness of the zero line even with deep Frequencies guaranteed. There is also DC coupling from the inputs 11 and 12 via the Y-divider to the output of the electron switch.

Through the exclusive use of cathode inserts in the scarf In addition, there is no significant potential jump between the input branch and output of the electronic switch, which is otherwise due to special measures (splitter coupling, Glow lamp splitter, tube coupling, etc.) would have to be overcome. For this reason the output of the electron switch can also be connected directly to the Y input will. The advantages of connecting the electron switch upstream of the Y input, and the Ways to make this possible are thus explained.

In summary, it should be mentioned again, in which the main advantages a device according to the invention compared to previously known are: 1. Differential amplifier have so far mainly been used in the low-frequency area to avoid disruptive influences to be able to compensate by symmetry of the input. The disturbances came here especially mains hum or similar phenomena. Present differential amplifier with its high bandwidth is primarily intended as a differential voltage measuring amplifier, for example, about the voltage drop on a one-sided not connected to ground Measure object.

The application is advantageous, for example, on a flip-flop circuit, at what voltage differences between grids and cathodes, grids and anodes etc. are to be measured. Likewise, voltages can be "floating" in networks be measured.

2. The optional combination of the electron switch with the broadband amplifier enables either the investigation of two separate processes via the electron switch or the differential voltage measurement between two high points with the differential amplifier.

In both cases, the novel voltage calibration when using only one channel a considerable simplification of the voltage measurement in the oscillogram achieved. All the more so. than they are in front of you without interrupting the measuring process can go. Both via the electronic switch and the differential amplifier DC coupling is provided, the oscilloscope achieves the accuracy a good tube voltmeter. The accuracy can be increased by partial enlargement in the Y-axis can be increased.

3. The use of a circuit to generate a negative capacitance in the Y-amplifier considerably reduces the tube expenditure for a given edge width. so that a particularly favorable solution is achieved here.

4. The design of the electron switch exclusively with cathode amplifiers avoids a large potential jump between the input and output of the electron switch so that this can act directly on the input of the differential amplifier. It is particularly important that the cathode amplifiers have low output resistances and therefore there is no noticeable frequency response at this point, so that the frequency response using the electron switch is almost that of the downstream Y amplifier corresponds.

Claims (22)

PATENT CLAIMS: 1. Electron beam oscilloscope, its Y amplifier is characterized by the combination of the following features: a) a circuit arrangement, in which a 1'-differential amplifier with a per se known electronic Switch cooperates; b) a circuit arrangement for voltage measurement with the aid the electronic switch, consisting of a controllable calibration voltage source, which optionally emits a calibration voltage that is positive or negative towards zero and a voltmeter to display the calibration voltage and a switch that controls this calibration voltage optionally supplies a channel of the electronic switch as a shift voltage; c) a circuit arrangement with a changeover switch for voltage calibration with the aid of the Y differential amplifier. in which the changeover switch is designed. that the calibration voltage optionally one The input of the differential amplifier is supplied as a shift coupling; yours Circuit arrangement for the compensation of harmful capacitances in the differential amplifier a network is provided which is like a capacitance with a negative sign acts and which consists of an additional amplifier stage, the output side works as a cathode amplifier, whose anode circuits also have a cross-coupling are connected to the grid on the input side and their negative capacitive reactive current is determined by the capacitive load on the cathode circuit. 2. Oscillograph according to claim 1, characterized. that for Achieving the symmetry a cathode-coupled amplifier stage at the differential input is provided, the preferably also cathode-coupled further amplifier stages are connected downstream to maintain symmetry. 3. Oscillograph according to claim 1, characterized in that the Y amplifier the coupling splitter for generating a potential difference through one dimensioned in this way Capacitor is bridged that a transmission of higher frequencies with a divider ratio of almost "one" is achieved, whereby the direct current component and the low frequencies, which are reduced by the coupling splitter, are emphasized. 4. Oscillograph according to claim 1, characterized in that the electronic switch is connected upstream of the differential amplifier and by means of a manually operated switching element an optional application of the differential amplifier alone or together with the electronic switch is possible. 5. Oscillograph according to claim 1, characterized in that two Y input step dividers can be operated separately and either on the inputs d. of the electronic switch or switchable to the differential amplifier inputs are. 6. Oscillograph according to claims 1 to 5 with differential input and electronic switch, characterized in that an adjustable, variable Calibration voltage (direct voltage) is provided, which can be read on a voltmeter and acts on one of the two input channels. 7. Oscillograph according to Claims 1 to 6, characterized in that that in the case of voltage calibrations with the differential amplifier switched on, the through the calibration voltage applied to one of the two differential inputs Y-position-Verscqlliehung can be read directly as a displacement voltage on the voltmeter. 8. Oscillograph according to Claims 1 to 6, characterized in that that when using the electroii i scheu 5 switch, the variable calibration voltage so on one of the two inputs of the electronic switch acts as one The level line assigned to this input appears, its changeable voltage level can be read directly on the voltmeter. 9. Oscillograph according to Claims 1 and 6, characterized in that that the two Y-input dividers, which with their output optionally to the input of the electronic switch or act on the differential input, one each Cathode amplifier is connected downstream. 10. Oscillograph according to claim 1, characterized in that the Means for shifting the Y position in front of the fine amplitude controller but behind the Intervene input divider. 11. Oscillograph according to claim 1 and 5, characterized in that the electronic switch with two cathode amplifiers, which are on the output side act a common cathode resistor and alternately by a switching voltage are opened and closed, is provided. 12. Oscillograph according to claim 11, characterized in that the Switching voltage is obtained from a flip-flop circuit, which is the timing frequency binary divides. 13. Oscillograph according to claims 11 and 12, characterized in that that the circuit is designed so that the switching voltage of the signal voltage is additive is superimposed. 14. Oscillograph according to claims 11 to 13, characterized in that that the switching voltage of the two cathode amplifiers around an equilibrium point tilts, which is determined in terms of potential by the potential of the common cathode is. 15. Oscillograph according to Claims 1 and 11, characterized in that that one of the grid cathode capacitance of the interrupter is functionally equivalent compensation element is provided and to act on the second input of the differential amplifier is brought. 16. Oscillograph according to claims 11 to 14, characterized in that that the switching voltage works tilt-synchronously and the switchover to the tilt return is laid. 17. Oscillograph according to claim 16, characterized in that the Tilt return runs darkened so that the switching interference voltage does not affect the screen got. 18. Oscillograph according to claim 12, characterized in that the Flip-flop circuit limiter stages are connected downstream, which control the switching voltage deform into an almost ideal square-wave voltage. 19. Oscillograph according to claim 9, characterized in that in the Y-amplifier double triodes are used, their grid anode capacitances are compensated by cross coupling. 20. Oscillograph according to claims 1, 9 and 19, characterized in that that between the cathodes of a cathode-coupled push-pull stage a controllable Negative coupling is provided for regulating the Y amplitude. 21. Oscillograph according to Claims 1, 9 and 19, characterized in that that a frequency-dependent negative feedback between the cathodes of a 1 'amplifier stage is intended for equalization of higher frequencies. 22. Oscillograph according to claim 21, characterized in that the External resistances of this tube stage are dimensioned so that they are suitable for medium frequencies results in an optimal dynamic range, while the negative feedback is dimensioned in such a way that that the high frequency response resulting from this design of the anode circuit damaging capacities are almost compensated. Publications considered: Rohde and Schwarz-Mitt., 2/1952, Pp. 98 to 105; Radio mentor, 11/1955. P.686 to 689; K 1 e i n, "electron beam oscilloscope". 1948, pp.105, 171 to 180; C z e ch »The electron beam oscilloscope«, 1955, p.67, 68.68 to 82, 89 to 95 and 180 to 185; Radio technology, 6/1955. P. 151. i52.