DE1935411B2 - Arrangement for sampling periodic signals - Google Patents

Description

The present invention relates to an arrangement for sampling periodic signals with a to sensing signal on a transmission line receiving input and with one behind the transmission line input to this coupled signal decoupling circuit.

Arrangements for sampling periodic signals of the aforementioned type are known from US Pat 41 076 and 32 78 846 become known.

The US-PS 3241 076 describes a circuit for Sampling of HF signals with a short-circuited transmission line carrying the HF signal. A keyed signal decoupling circuit is in particular

special inductively coupled to the transmission line It usually contains blocked diodes, which are switched on by touch signals, see above that with conducting diodes sample values are taken from the signal running over the transmission line can be.

Such a configuration of the gated signal extraction circuit however, has the disadvantage that the rise time of the sampling pulses greatly affects the sampling speed is received If a diode is switched from the blocked to the conductive state, it must first of all the start-up area up to the threshold voltage in the forward characteristic of the diode is passed through. In this starting area, the diode hardly conducts at all. Only when the start-up area has been run through the diode fully conducts beyond the threshold voltage. In the forward characteristic range beyond the start-up range the full forward current is practically independent of the time course of the above the threshold voltage lying forward voltage. With finite rise time of the forward voltage, what for the present Case of the finite rise time of a key pulse when to be switched by the key pulse in the forward direction Diode corresponds to the keying speed is determined by the time in which the key pulse to

ju to the diode threshold voltage increases

The same applies to an arrangement according to US-PS 32 78 846, in which the coupling also via a normally biased in the blocking direction, is carried out by a key pulse conducting diode

The present invention is based on the object of an arrangement for keying periodic To indicate signals with a higher scanning speed.

In an arrangement of the type mentioned at the outset, this object is achieved according to the invention by the following Features solved:

at least one between the input of the transmission line and the signal decoupling point in the Line routing switched on gate circuit, which is controlled in such a way that a signal is sent to the signal decoupling circuit coupled part of a predetermined length of the transmission line is repeated from the remaining one Part of the transmission line can be switched off and

thus acts as a memory for different values of the input signal during the switch-off times Input is fed into the transmission line and the transmission line in from the shutdown times cycles completely through different times

In the arrangement according to the invention defined above, in which the gate circuit is preferably is designed as a diode circuit, a switchover of the diode gate circuit takes place for the keying process from the pass band into the stop band.

Mi Even relatively small voltage changes in the transmission range due to the steep course of the transmission characteristic range of diodes beyond the Ξ: hwell voltage are sufficient to switch the diodes into the starting range in which they are practically already

hi no longer lead. The slope i.e. the The rise or fall time of the key pulse is therefore not as much a factor in the key speed as this when switching the diodes from the SDerrbereich to the

Passband is the case in the previously known arrangements

Refinements of the inventive concept are characterized in the subclaims.

The invention is explained in more detail below with reference to exemplary embodiments shown in the figures of the drawing

F i g. 1 shows a first embodiment of a key arrangement according to the invention;

F i g. 2 shows a schematic representation of a second embodiment of an arrangement according to the invention;

3 shows a schematic representation of an improved embodiment of the arrangement according to FIG. 2;

FIG. 4 shows a plan view of a preferred exemplary embodiment of an arrangement according to FIG. 3 with one schematic operating diagram;

5 shows a schematic representation of a third Embodiment of the key arrangement according to the invention;

F i g. 6 is a schematic representation of a generalized embodiment of the arrangement according to FIG Fig. 5;

F i g. 7 shows a block diagram of a touch oscilloscope with a key arrangement according to the invention;

8 is a partially broken away plan view an arrangement according to the invention which is mounted in a holder;

F i g. 9 is a section along line 9-9 in FIG. 8th; and

Fig. 10 is a partial section along line 10-10 in Fig. 8.

The in F i g. The embodiment of the arrangement according to the invention shown in 1 contains a coaxial transmission line 10 with an input 12, to which a source delivering periodic high-frequency signals can be coupled, and with a resistor termination 14. The resistor termination 14 has an impedance value which is equal to the characteristic impedance Z _{0 of} the transmission line has an outer conductor 11 and a central inner conductor 16. In the course of the line, first and second gate circuits 18 and 20, connected in series, are coupled into the inner conductor 16, between which a part 22 of the transmission line remains as a remainder 26 comprehensive signal decoupling circuit coupled In order to avoid a line joint as a result of mismatching, the decoupling element 26 can be formed by a gate circuit or a relatively high resistance. The signal decoupling circuit is expediently connected to a preamplifier, not shown in this figure, the output of which is connected to an oscilloscope

Between the inner conductor 16 and the outer conductor 11 of the transmission line are coupled in a high-frequency input signal generally for a specific time period, the gate circuits 18 and 20 are conductive, so the signals are longitudinally passed the line and through the terminating resistance Z ₀ absorbed In general, the responsiveness of of the preamplifier connected to the output conductor 24 slowly with respect to the positive or negative changes in the input signal and, moreover, the preamplifier is also connected to the transmission line via the decoupling element 26, which is expediently an open switch or a relatively high-resistance resistor

Furthermore, the input signal is expedient

only for a relatively short period of time compared to that

Sensitivity of the preamplifier, applied

which is still big enough to be stable

To effect transmission ratios on the line. Therefore, the preamplifier can not do much Measure by the one at the entrance of the transmission line

applied input signal can be actuated.

If a keying is to take place, the

Gate circuits 18 and 20 locked to the part 22 to decouple the transmission line from the rest of it. The gate circuits 18 and 20 can during the Occurrence of successive parts of periodic input signals to be sampled are blocked. if the gate circuits 18 and 20 are blocked, the portion 22 of the transmission line temporarily stores a Relatively constant value of the input signal according to the value present during keying The rise time of the probe assembly is through time given what the shaft needed to get from the To run gate circuit 18 to gate circuit 20 This statement contains a certain approximation and sets assume that the gate circuits 18 and 20 have no forward resistance when turned on and that they are essentially abrupt, i.e. H. can be switched off during the period zero If a flank of a square-wave pulse runs along: the line between the switched-off gate scarf propagates, the line part 22 remains eir mean equal potential of the square-wave pulse impressed after the captured signal several times into the Line section 22 has been reflected back and forth. In fact, the decoupling element 26 is switched on as soon as the gate circuits 18 and 20 are blocked have been, so that the signal decoupling circuit with is connected to the preamplifier and an average value of the captured signal is sent to the preamplifier is released more strongly. In the event that the decoupling element is formed!

26 as an ohmic resistance, its value must be large compared to the characteristic impedance Z _{0 of} the transmission line. The signal output from the preamplifier is particularly effective when the decoupling element Ά has such an ohmic resistance R and dei Line part 22 have such a capacitance C that this βC element has a time constant which is in the same order of magnitude as the response or rise time of the preamplifier. The period of temporary storage on the line is here

so at least comparable to the response time de: Preamplifier.

After keying and shortly before the following keying, the gate circuits 18 and 2 ( turned on and the decoupling element 26, if there is one Switch contains, turned off, so that the input si gnal can in turn advance along the transmission line to terminal 14. The keys succeed hence, by temporarily severing a portion of the transmission line which is called temporary

The storage element for the sample value is used by Da di < Grid circuits 18 and 20 only switched off

must be in order to take a sample value the keying is much faster and more predictable.

The gate circuits 18 and 20 can, for example

wise contain diodes or triodes. The gate scarf lines can receive a key signal, which both simultaneously by not shown outer circles zi is fed to certain scanning times. On the other hand

The gate circuits 18 and 20 can also contain semiconductor diodes with the same polarity, which with the help of are switched alternately conductive or non-conductive by sharp tactile impulses, which via the termination 14 can be created. It is immediately evident that an edge of this key pulse first triggers the gate circuit 20 and then the gate circuit 18 is actuated, since these pulses are on the line from right to left in F i g. 1 propagate. The rise time is then twice as long as the time it takes for a wave to move from the To run gate circuit 18 to gate circuit 20, d. H. the rise time is equal to the sum of the time it takes it takes the input signal to travel this distance and the time it takes for the wavefront of the Switching pulse needs to cover the same distance in the opposite direction.

In general, gate circuits 18 and 20 are like polarized diodes, which are normally so are biased that they are in the locked state. The key pulse becomes the transmission line supplied to the gate circuits 18 and 20 during a predetermined period of time in the switched on To keep state. Then the key pulse is switched off, so that the part 22 of the line has a key value of the input signal. The capacity of the part 22 of the transmission line is usually large smaller than the input capacitance of the preamplifier, which is fed to the signal decoupling circuit 24, 26 connected. After the keying, the charge stored on the part 22 of the transmission line the input opacity of the preamplifier is supplied via the decoupling resistor 26

F i g. 2 shows an embodiment in the form of an arrangement with matched lines. First is one First transmission line 28 is provided, which contains a first coaxial line which is connected to an input 30 an input signal can be supplied. The transmission line 28 includes an outer conductor and an inner conductor and extends to a signal output 32, which in a suitable manner to a switching voltage generator or a corresponding stage of a Oscilloscope is connected and has an input impedance that corresponds to the characteristic impedance of the line 28, e.g. 50 ohms, corresponds to a second and third line 34 branching approximately in the middle of the line 28 and 36 from the line 28, the inner conductors of the lines 34 and 36 with the inner conductor of the line 28 and the outer conductors of lines 34 and 36 are connected to the outer conductor of line 28, so that in the essentially a parallel connection of the transmission lines comes about at the input 30 of the Line 28 applied input signal is therefore not only towards the output 32, but also Continue to the left and right through lines 34 and 36 as soon as the signal passes this intersection has reached the lines

Semiconductor diodes 38 and 40 are arranged in series along the inner conductor of the line 38 and are at a distance L ₁ from one another along the line. The diodes are polarized in the same direction, ie both are directed with their cathode-side ends towards the inner conductor of the line 28.

Correspondingly, the inner conductor of the line 36 is connected to semiconductor diodes 42 and 44, which are in series connected along this and arranged in the same Are polarized in the same way as diodes 38 and 40. This means that a direct voltage applied across all these diodes switches all diodes either conductive or non-conductive, depending on the polarity of this voltage. The diode 42 is arranged approximately at the same distance from the inner conductor 28 as the diode 40, and furthermore the diodes 42 and 44 are separated from one another by approximately the distance L \. Approximately in the middle between the diodes 42 and 44 is a signal decoupling circuit which contains a resistor 46 is connected to the inner conductor of the line 36. The remaining ends of the resistors 43 and 46 are coupled together via conductors 80 and 82 to to supply a key signal to a preamplifier, wherein

is in conductor 80 between resistor 43 and the common connection point a capacitor 48 is connected in series. The capacitor 48 provides for a coupling of the resistors, insofar as it is the key signal, while it is a DC voltage represents adequate decoupling, so that the diodes suitable biases can be applied.

The values of the resistors 43 and 46 are at

a practical embodiment about 16 kOhm.

One end 50 of the line 34 and one end 52 of the

Line 36 are fed to probe signals of opposite polarity, these probe signals are taken from generators, the output impedance of the Characteristic impedance of the line, e.g. B. correspond to 50 ohms. While the pulse is applied, it increases Potential at the input end 50 from a negative to a positive value, while the end 52 of the line 36 drops from a positive value to a negative. The polarity is while the probe pulses are applied so overall so that the diodes 38, 40, 42 and 44 are conductive. The pulse pulses are slightly longer than twice the transit time along a line L \. For example, the strobe pulses are generally 100 picoseconds long with a comparatively higher tracking frequency of, for example, 10 microseconds. The tactile impulses have very sharply sloping rear flanks. While the tactile impulses are applied, it is implanted in the Input 30 of line 28 applied input signal along both lines 34 and 36, this Input signal to the preamplifier but not significantly can affect, especially because of the short Duration of the tactile impulses. The duration of the strobe pulses is desirably short compared to that slower response time of the preamplifier while being large compared to twice the running time

such a wave along the line section L \. At the end of the sampling pulses, all diodes become non-conductive, so that the sampling value of the signal in lines 34 and 36 between diodes 38 and 40 or 42 and 44 is stored as a charge over a relatively long period of time so that during this time the preamplifier can address. This charge is fed to the preamplifier through resistors 43 and 46

The embodiment of the present invention according to FIG. 2 has the aforementioned advantages; H. it has a very high scanning speed with a typical repetition rate of around 100 kHz Rise time is smooth and predictable. A low forward resistance is obtained because the Diodes from a state of full conductivity in a state of non-conductivity can be changed which leads to an improvement in charge storage and low noise. the Noise ratios are what you get with a

Arrangement would be obtained which has about two and a half times lower sensitivity. The arrangement is also not particularly critical with regard to the probe pulses as long as only the trailing edge dw / dt of the probe pulses is steep compared to any signal changes, since only the trailing edge is important. 2 has additional advantages because of the structure with adapted lines. As a result of using balanced, compensating tactile pulses with opposite polarity, there is less influence of the tactile pulses in the input signal circuit, i.e. via input 30 of line 28. For the same reason, the preamplifier basically only detects the stored parts of the input signal instead of the tactile pulses itself. In addition, an arrangement with matched lines is relatively insensitive to temperature effects of the diodes.

In the embodiment according to FIG. 2, the rise time for the scanning process is twice as great as the time which a wavefront needs to traverse the distance L \. As in connection with F i g. 1, the signal takes such a unit of time to move outwardly from the line 28 in the lines 34 and 36, while the equally large second unit of time is required by the tactile pulses to travel the same distance inward.

The embodiment according to FIG. 3 is constructed quite similarly to the arrangement according to FIG. 2, identical parts are provided with the same reference numerals. This embodiment also includes however still diodes 54 and 56 which are polarized in the same direction as the other diodes between the Inner conductors of the line 28 and the diodes 40 and 42 are arranged. A bias circuit with resistors 58 and 60 biases diodes 54 and 56 such that they are normally absent of tactile pulses are non-conductive. Accordingly, a resistor 58 connects the junction between the cathode of the diode 40 and the anode of the diode 54 via a conductor 76 with a first Bias source, while resistor 60 is in communication between the cathode of diode 56 and the Anode of the diode 42 connects via a conductor 78 to a second bias voltage source. Between Bias sources and ground are connected to capacitors 62 and 64 to provide signal cross-coupling switch off the power supply. The bias voltages are chosen so that the cathode each The diode is normally positive with respect to its anode when there are no key signals.

The purpose of the additional diodes 54 and 56 is to compensate for crosstalk, whereby one this crosstalk as coupling of an input signal through the capacitance of the diodes 40 and 42 in the Can define preamplifier in the absence of a key signal. The use of the additional diodes 54 and 56 together with resistors 58 and 60 ensure a first differentiation of the crosstalk signals, while the diodes 40 and 42 in combination with the resistors 43 and 46 perform a second differentiation of the Cause crosstalk signals. Since a given signal change before it reaches the preamplifier, is differentiated twice, it then shows positive and negative changes that are approximately equally strong, see above that it has only a very small effect on the preamplifier. So such a signal is practically turned off. In addition, the structure and the mode of operation of an exemplary embodiment according to FIG. 3 essentially the same as in connection with the exemplary embodiment according to FIG F i g. 2 has been described.

F i g. 4 shows an advantageous form of construction of an arrangement according to FIG. 3, with corresponding parts again with the same reference numerals as in FIG. 3 are provided. The respective transmission lines

ίο are designed as ribbon cables, which the inner conductor represent, which is applied to an insulating ceramic plate 66, which in turn is spaced between two to it arranged grounded flat plates 68 and 70 is arranged, as the outer conductor for the transmission lines to serve. Inner conductors 28 ', 34' and 36 'correspond to the transmission lines denoted without dashes in Fig. 3. Diodes 38 ', 40', 54 ', 56', 42 'and 44' are very small, non-encapsulated semiconductor diode plates, which are connected in series with the inner conductors 34 'and 36'. These platelets are pretty thin and soldered onto the strip conductor, while short connecting lines connect the diode junctions to the Connect the tip of the platelets to the next section of ribbon cable. Resistors 43 ', 46', 58 'and 60' are vapor-deposited or printed resistors, which are in the same relative position to one another as they are in Fig. 3 is shown. These resistances partially overlap here with the strip conductors, and the more so get electrical contact with them and

to simultaneously overlap the ends of conductors 76 ', 78', 80 'and 82' deposited on the ceramic plate 66 are. The exemplary embodiment according to FIG. 4 also contains separated protective conductors 72 and 74, which by short pieces of wire with conductors 76 'and 78'

j5 are connected to prevent capacitive coupling between conductors. The protective conductors 72 and 74, together with the conductors 76 'and 78', are connected to DC voltage bias points and grounded in terms of alternating current via capacitors 62 and 64. They prevent a capacitive coupling, for example, between the inner conductor 28 'and the vapor-deposited conductors 80' and 82 'and thereby prevent undesired coupling at this point.
The input of the conductor 28 'is connected to a socket 84, while the output of the conductor 28' is connected to the circuit of an oscilloscope via a socket 85 and a voltage divider 86. The ends 50 'and 52' of the conductors 34 'and 36' are each connected to a key pulse generator for generating the positive and negative key pulses. The ends 50 'and 52' of the conductors 34 'and 36' are also connected to taps of a voltage divider which contains resistors 92, 94, 96 and 98 as well as a potentiometer 100 and is located between positive and negative voltage terminals. Resistor 92 is between conductor end 50 'and a negative voltage terminal, while resistor 94, potentiometer 100 and resistor 96 are connected in series between end 50' of conductor 34 'and end 52' of conductor 36 '. Resistor 98 is between conductor end 52 'and a positive voltage terminal. The tap 102 of the potentiometer 100 is connected to a bias voltage source, the potentiometer being used for adjustment. The bias can be obtained by feedback from the envelope detector of the oscilloscope, as will be explained in more detail below. The voltage divider ensures that the diodes are connected in series

standing voltage that normally keeps the diodes in a non-conductive state.

A second voltage divider with resistors 104, 106, 108, 110 and 112 connects the ends SO 'and 52' the conductors 34 'and 36'. Conductor 76 'is with the junction of resistors 106 and 108 while conductor 78 'is connected to the junction between resistors 108 and 110 is. These connection points are also connected to the conductor ends 50 'ι ο by capacitors 114 and 116 and 52 'connected. Conductor 80 'is across to the junction of resistors 104 and 106 a resistor 118 is connected, while the conductor 82 'is similarly connected to the connection point of the Resistors UO and 112 across a resistor 120 is located. The resistors 43 ', 58', 60 'and 46' with corresponding points along the transmission line are connected to points of the voltage divider 104, 106, 108, 110, 112 connected that each of the diodes 38 ', 40', 54 ', 56', 42 'and 44' individually one Receives voltage that biases it in the reverse direction. However, if the pulse generator output pulses supplies, the voltage on the voltage divider is reversed, so that all diodes then conduct.

At the end of the strobe pulses, the diodes return to their original non-conductive state. However, the decoupling resistors 118 and 120 are so large that the temporarily stored values are not short-circuited the input signal on the conductor sections 34 'and 36', which are μ connected to the resistors 43 'and 46', but through the resistors 118 and 120 coupled to the preamplifier. Since the arrangement is symmetrical, the temporarily stored sample values of the input signal from the conductors 80 'and 82' are essentially the same size, while the sample pulses compensate each other. The general mode of operation of this exemplary embodiment corresponds essentially to that of FIG. 3.

A more exact and detailed physical representation of a preferred embodiment of a ceramic plate 66 together with the associated surrounding part is shown in FIGS. 8 to 10, where again the same elements are provided with the same reference symbols. The plate 66 is small and has a base area of approximately 10 × 20 mm with a thickness of approximately 0.4 mm. The distance between a ribbon line and the planar conductors 70 and 68 is approximately 0.6 mm in this particular embodiment. The double transit time corresponding to the distance L \ of the transmission line (z. B. between the diodes 38 'and 40') is about 15 microseconds. The lines are therefore very short and fast and allow very short sections of the input signal to be saved and keyed.

The ceramic plate 66 together with the miniature diodes 38 ', 40', 54 ', 56', 42 'and 44' and the resistors 43 ', 46' 58 'and 60' represent an integrated hybrid circuit, the diodes and resistors not being encapsulated Layer elements are. As can be seen from the drawings, the diodes and resistors are small compared to the structure of the transmission line. The diodes and resistors lie essentially flat on the ceramic plate 66, so that these integrated hybrid circuit components themselves produce only very low capacitances and thus only very little or no effect at all on the mode of operation of the transmission line. These parts also represent only very small joints in the transmission line, assuming that the diodes are conductive and the ohmic resistance values of the resistors are large compared to the characteristic impedance Z _{0 of} the line. In addition, the diodes and resistors are mechanically and electrically connected directly to the ribbon line, ie by conductors whose length is zero or almost zero, which accordingly cause only a practically negligible delay, so that the operating speed of the circuit is high. Because of the extremely short lead length, which results in minimal delay, and because of the low shunt capacitance generated by the resistors and diodes, the construction shown creates a fast-working arrangement which can pick up and process very high-frequency signals.

The arrangement described above also enables one for very high-frequency signals Execution in integrated technology. The very small non-encapsulated and tightly stacked components increase the speed while the flat strip conductors 68 and 70 remove the exposed sensitive ones Protect parts and the ceramic plate from damage.

According to FIGS. 8 and 10, the ceramic plate contains 66 in its preferred embodiment a plurality of slots 106 extending through the plate and disconnect the parts of lines 34 'and 36' connected in series by diodes. The production the ceramic plate 66 is expediently carried out by dry pressing into the desired shape, so that also the slots 160 are already present and subsequent firing, with ceramic material for the hybrid integrated circuit is preferred because of its excellent dielectric properties. The slots 160 reduce the capacitance between parts of lines 34 'and 36', with the dielectric constant between line parts is reduced essentially to the value of air. This makes the capacitive Coupling via diodes 38 ', 40', 54 ', 56', 42 'and 44' is reduced.

The ceramic plate 66 is slidably mounted in a slot 162 formed in a unitary holder part 164 is formed, the inner surfaces 68 'and 70' of this holder 164, which are at a certain distance form flat outer conductors arranged on each side of the ceramic plate. The surface 70 'is an integral part of the Holder 164, while surface 68 'is represented by the inner surface of an insert 166 which is attached to the holding body by a braze 168.

The holder 164, together with the insert 166, has cylindrical bores for receiving pins 172 Mistake. The pins 172 pass through openings 174 of the ceramic plate 66 and thereby form devices to to releasably secure the ceramic plate in slot 162. The openings 174 are slightly larger than the diameter of the pins so that limited movement of the plate 66 in the slot is possible even when the pins are inserted. The final positioning of the plate can be determined by spring fingers 176 on a mounting plate 178 take place. These spring fingers contact the ends of conductors 76 ', 78', 80 'and 82' as well as that Ends 50 'and 52' of lines 34 'and 36', all of which extend around the edge of plate 66, around one to make suitable contact with the spring fingers. As can be seen from the drawings, the ladder is 76 ', 78', 80 'and 82' so applied to the plate 66 that

they avoid the recesses {74 and pins 172. The holder 164 contains corner brackets 180 which are provided with openings for receiving screws 182 are, which are used .. to releasably attach the body 164 to the mounting plate 178, which in turn Is part of a larger device. For example, this device can have an additional one shown in FIGS included circuit shown. The screws only need to be loosened if the wants to remove the entire part from the device, d. H. for replacement or repairs. If the Holder 164 is returned to the circuit board, the spring fingers in turn contact the conductors the edges of plate 66, also providing final positioning of the plate so that each finger engages in the correct line.

The holder 164 includes end walls 184 between which the insert 166 is secured and with Threaded bores are provided to form sockets 84 and 85 which are used to receive coaxial cable connectors 190 and 192. The coaxial cable connectors 190 and 192 are spring loaded Inner conductors 194 and 196 are provided to the respective ends of the conduit 28 'which extends around the edge of the Plate 66 extend to contact when connectors 190 and 192 fully engage sockets 84 and 85 are inserted. The bushings 84 and 85 have stop shoulders 198 and 200, so that a special an advantageous electrical transition between the coaxial cables and the ribbon cable is established, with the coaxial connectors fully inserted into the sockets and against the shoulders issue. By using the coaxial cable connectors, which have a grounded outer conductor contained in the sockets 84 and 85, the holder 164 grounded with insert 166 so that surfaces 68 'and 70' form outer grounded planes for the stripline assembly.

Home! the ceramic plate 66 is very small and the Components attached to it are very sensitive as they reduce their size and capacity are not encapsulated, the overall construction of the holder 164 provides a substantially shock and vibration resistant housing for the ceramic plate and those thereon located components. The holder itself can be handled as an independent part. The ceramic plate and components are essentially enclosed and protected between the inner surfaces 68 'and 70', these surfaces being the flat Outer conductors for the strip line arrangement form and are the component parts of the transmission line. The combination according to the invention creates an arrangement with only insignificant reflections from any line joints and a transmission bandwidth that extends up to frequencies above from 18 GHz.

The combination shown in FIGS. 8 to 10 an integrated hybrid circuit and a ribbon cable is particularly advantageous for the cases mentioned above, for example a button arrangement, but can also be used with advantage for other devices in which signals with high frequency or high rate of change are processed should.

The F i g. FIG. 5 shows another exemplary embodiment of the invention, wherein a gate 126 is used to generate the To separate transmission line 124 from the input signal socket 136 at certain sampling times. The gate 126 here contains a diode bridge with a first pair of equally polarized diodes 132 and 134, whose Center tap is connected to socket 136 and to a second pair of equally polarized diodes 128 and 130, the center tap of which is connected to the transmission line 124. The diode pairs are parallel switched and normally biased so that they are in the non-conductive state, so that no Input signal can pass through the gate. However, tactile impulses with the one in the drawing If the specified polarity is applied, the diodes become conductive and couple the input signal to the Transmission line 124.

The transmission line 124 can be of any suitable type, to which a signal decoupling circuit is connected, which in the present case contains a resistor 138 which is preferably of high impedance compared to the characteristic impedance of the transmission line. If the gate 126 is controlled to be conductive by the strobe pulses, the input signals propagate along the transmission line 124. The duration of the probe pulses is short, based on the response time of the preamplifier connected to resistor 138, but long compared to twice the transit time of a wave along a transmission line section of length L \. This has already been explained in the previous exemplary embodiment. These measures achieve stable transmission conditions on the line As in the previously described embodiments, the transmission line acts as a temporary storage element after the sampling pulses have ceased, a sample value of the input signal being stored which was just traveling along the line 124 when the sampling pulses ended. This sample value of the input signal is stored long enough to activate the preamplifier connected to resistor 138. The rise time is in turn twice as large as the transit time for a wave along a section of the line Li

The diode bridge 126 in FIG. 5 is particularly preferred because it is a compensation at the same time of crosstalk effects; however, it is also possible to use other gate arrangements. F i g. Figure 6 shows a generalized arrangement with gate 126 shown as a box, which means It should be made clear that various other forms of gates can also be used.

F i g. 7 shows an oscilloscope circuit which operates with a probe arrangement according to the invention. In Fig. 7th A block 140 represents the button arrangement to which the input signal is fed via a terminal 148. When a selected sampling point of the input signal occurs, the pulse generator 88 generates one Switching pulse which is fed to a high-frequency sawtooth generator 150. The sawtooth generator generates a rapidly falling voltage edge which is fed to one input of a tracking pulse generator and comparison stage 152. The other The input of this stage 152 receives a step-shaped voltage from a stage voltage generator 154. Every time the steep voltage edge drops to the level of the staircase voltage, the actuates Comparison part of stage 152 the tracked pulse generator part. This in turn actuates the Probe arrangement 140 associated probe circle. At the same time, the tracking pulse generator and Comparison stage 152 the stair tension of the stair

Voltage generator 154 by one unit. At the next sampling time, the steeply falling The voltage edge must first have fallen to the new level of the staircase voltage before turning on again Comparison can take place so that the delay s between the trigger time and the generation of the tracked pulses from stage 152 is increased The amount of time by which the tracked Pulses are delayed compared to the sampling time depends on the inclination of the voltage edge and the ι ο The level at which the stair tension is located. In this way, the Probe arrangement opened at later and later times, based on the original scanning time, so that sample values of the input signal at different repetitions from different areas of the Input signal.

Horizontal deflection voltages provided by a horizontal amplifier 156 move a point on a cathode ray tube 146 in steps with the tracked pulse. The horizontal Deflection voltage for the horizontal amplifier 156 is generated in accordance with the staircase voltage from the staircase voltage generator 154, which is as mentioned above was changed after each sample so that the point on the cathode ray tube 156 changes for each sample moved horizontally

The vertical channel of the arrangement according to FIG. 7 contains the probe arrangement 140, which takes short sample values of the input signal, and a storing one Envelope detector 142 which stores the level of each sample until a new sample is taken Envelope detector 142 receives the output signals of the preamplifier connected to the probe arrangement. The output of the envelope detector 142 becomes 3S fed to the vertical baffles of the cathode ray tube 146 through a vertical amplifier 144, wherein the one on the cathode ray tube screen visible point when removing a key value a vertical level is deflected, which corresponds to the level of the input signal at the moment, in which the keying takes place The point remains because of the memory effect of the envelope curve detector 142 stationary on the screen until the next keying occurs

Each subsequent scan sets the same chain of events in motion. However, since the staircase tension is down one step each time moves, the falling voltage edge of the saw tooth must go down a little further each time before the comparison part can generate a comparison pulse. In this way, the keying is always longer Time intervals delayed and the sample values, which are taken one after the other from the input signal, take place at later times, based on the Sampling time With each sampling, the position of the point on the screen of the cathode ray tube moves horizontally by one unit and possibly also to a new vertical level. Since the Sensor channel responds to deviations, the vertical position of the point on the screen only changes if the input voltage has changed between successive touch points It is immediate It can be seen that by such an arrangement it is possible to see the input waveform on the screen Imagine the cathode ray tube with a relatively small frequency by viewing the very much higher frequency input waveform composed of successive samples The arrangement according to FIG. 7 has been shown in detail in order to better explain the advantages and mode of operation of the present invention. It goes without saying even that the present invention is also used in connection with other oscilloscope circuits Can be used.

For this purpose 3 sheets of drawings

80S 533/44

Claims (26)

Patent claims: 1. Arrangement for sampling periodic signals with a signal to be sampled on one Input receiving transmission line and with one behind the transmission line input signal decoupling circuit coupled to this, characterized by at least one between the input (12) of the transmission line (10) and the signal decoupling point in the. Line routing switched on gate circuit (18), which is controlled in such a way that a part of a predetermined length of the transmission line (10) coupled to the signal coupling circuit (24, 26) repeats can be switched off from the remaining part of the transmission line (10) and as a memory for different values during the switch-off times? of Acts input signal that is fed into the transmission line (10) at the input (12) and the Transmission line runs through completely in times different from the switch-off times 2. Arrangement according to claim 1, characterized in that the signal decoupling circuit (24, 26) includes a resistor (26) coupled to the transmission line (10) 3. Arrangement according to claim 1 or 2, characterized in that the gate circuit (18) as Diode gate is formed. 4. Arrangement according to one of claims 1 to 3, characterized in that the transmission line (10) is normally through a resistor (14) is completed, the size of which corresponds to the wave resistance of the line 5. Arrangement according to one of claims 1 to 4, characterized in that the memory J5 acting part (22) of the transmission line (10) two gate circuits (18, 20) are coupled, one of which serves to interrupt the transmission line that on part (22) of the Line the signal decoupling circuit (24, 26) ίο is coupled and that the gate circuits (18, 20) are controllable in such a way that they the part (22) of the Transmission line (10) can separate from the remaining part. 6. Arrangement according to claim 5, characterized in that a transmission line pair (34, 36) is provided, each of which has two gate circuits (38, 40; 42, 44) and between Signal decoupling circuits (43, 46) coupled to these gate circuits also contain w a third transmission line (28) is provided and that the inputs of the transmission line pair (34,36) jointly at one point of this third Transmission line are coupled. 7. Arrangement according to claim 6, characterized in that the outputs of each line of the Transmission line pairs (34, 36) are coupled together to form a common output (32). 8. Arrangement according to claim 6 or 7, characterized in that f> <· Indicated that the transmission line pair (34, 36) on the side (50, 52) remote from the third transmission line by key signals for the Gate circuits (38, 40; 42, 44) can be controlled in order to first make the gate circuits conductive switch and then to separate the memory sections of the two lying between them To switch transmission lines non-conductive. 9. Arrangement according to claim 6 to 8, characterized in that the gate circuits in contain diodes (38, 40; 42, 44) polarized in the same direction. 10. The arrangement according to claim 9, characterized in that the diodes (38, 40; 42, 44) in the Normal state are biased in the blocking direction. 11. Arrangement according to claim 9 or 10, characterized in that between the third transmission line (28) and the transmission line pair (34,36) each additional diodes (54, 56) with the same polarity are connected. 12. Arrangement according to one of claims 6 to 11, characterized in that the third transmission line extends over the transmission line pair (34,36) also extends to create a trigger signal for an oscilloscope, which is used for playback the stored sample values of the input signal 13. Arrangement according to one of claims 1 to 12, characterized in that the gate circuits (18, 20) are controlled by strobe pulses so that the Transmission line (10) is switched through for a certain period of time and that a longer period of separation of the storing line part (22) follows where at least during of the greater part of this latter time segment, the sample value im taken from the input signal Line part (22) is stored 14. Arrangement according to one of claims 1 to 4, characterized in that the gate circuit is designed as a diode bridge (128) connected between the input and output of the transmission line (124), the diode bridge a first pair (132,134) of diodes of the same polarity, the center tap of which with the input adjacent part of the transmission line, while the second pair of diodes (128, 130) connected in parallel to the first pair of diodes and having the same forward direction is coupled with its center tap on the part of the transmission line to which the Signal decoupling circuit (138) is located and that the diode bridge can be controlled by tactile pulses, which make them conductive or non-conductive alternately. 15. Arrangement according to one of claims 1 to 14, characterized by an amplifier for amplifying the signal at the signal decoupling circuit (24, 26) removable sample values of the input signal and an oscilloscope circuit to the output signals of the amplifier visible on a screen. 16. The arrangement according to claim 15, characterized in that the amplifier is substantially only responds during the storage period of the sample values 17. Arrangement according to claim 15 or 16, characterized characterized in that the response time of the amplifier is of the same order of magnitude as that Time constant of the signal decoupling circuit (24,26) together with the capacity of the storing Transmission part (22) and that the period of time during which the transmission line (10) through the Gate circuits (18, 20) connected to the input (12) is small compared to the response time of the Amplifier so that it cannot be operated directly by the input signal. 18. Arrangement according to one of claims 1 to 17, characterized in that the transmission lines (11; 28, 34,36) are coaxial transmission lines, the gate circuits (18, 20; 38, 40, 42,44) in series with the Inner conductors are switched. 19. Arrangement according to one of claims 1 to 17, characterized in that the transmission lines are ribbon lines, the inner conductors (28 ', 34', 36 ') being arranged on a common insulating plate (66) and first and second flat conductors ( 68, 70) are provided above and below the plate at a distance from it to form the outer conductors of a transmission line arrangement and that the gate circuits contain diodes (38 ', 40', 42 ', 44') which are on the insulating plate (66 ) are connected in series with the inner conductors (28 ', 34', 36 '). 20. Arrangement according to claim 19, characterized by the use of resistors and Diodes in the form of non-encapsulated, substantially planar, thick film circuit elements. 21. Arrangement according to claim 19 or 20, characterized by an interruption of Inner conductors (34 ', 36') and direct coupling to the gate circuits in the form of essentially flat diode disks (38 ', 40', 42 ', 44'). 22. Arrangement according to one of claims 19 to 21, characterized in that the two flat conductors (68 ', 70') are combined to form a unitary part (164) , with a slot between them for substantially complete accommodation of the insulating plate ( 66) it remains free that external connecting devices (176) are provided in order to contact the conductors on the insulating plate and that the part (164) can be releasably fastened to a larger arrangement by fastening devices (182) 23. Arrangement according to claim 22, characterized by means (172) to hold the insulating plate (66) releasably in the slot between the flat conductors (68 ', 70'). 24. Arrangement according to claim 22 or 23, characterized by coaxial connecting pieces (84, 190; 85, 192) in order to couple a coaxial cable to one of the conductors containing the inner conductor of a ribbon line. 25. Arrangement according to one of claims 19 to 24, characterized in that the insulating plate (66) consists of ceramic material. 26. Arrangement according to one of claims 23 to 25, characterized in that the devices (172) for releasably holding the insulating plate (66) in the slot are designed in such a way that the insulating plate can move to a limited extent in the slot and that the exact holding and positioning of the plate takes place with the aid of the connecting devices (176)