HU183699B - High-speed switching circuit of three-state - Google Patents

Abstract

The invention relates to a replaceable paper filter cartridge for Feinstfilterung of lubricants and hydraulic fluids mineral oil-based for use in lubrication and hydraulic circuits in automated machine tool systems. Using known filter papers and components without incorporation of metal mesh, a solution is presented which has a high filter fineness and a large dirt holding capacity. The paper filter cartridge essentially consists of a multi-perforated metal sleeve, which is made of a large perforated and made of a thin pressboard For the improvement of the differential pressure behavior and the dirt absorption particularly grooved support body as well as an overlying, folded, duenneren, kunstharzimpraegnierten filter paper is surrounded. The double folding creates a filter cartridge with good differential pressure behavior. The folded filter papers are sealed on the front side in sheet metal lid. The overlying filter paper has a resin content of 6% and up to 15% glass fibers. The filter cartridge must be installed in a housing for the purpose of performing the filter task.

Description

(57) EXTRAS

BACKGROUND OF THE INVENTION The present invention relates to a high-speed, three-state switching circuit arrangement which is mainly used as part of the pin electronics of digital circuitry measuring and testing apparatuses for switching voltage levels, particularly programmed logic Un and Ul voltage levels, and realizing an "open" state.

The current generators controlled by the three-state switch circuit arrangement of the present invention have switchable voltage level input and switchable voltage level per input. The circuit arrangement consists of receiving a drive signal receiving stage and a third stage controlling signal receiving stage, the first differential current amplifier having a first controlled current generator and a second differential amplifier having a first-stage current generator and a split-end biasing base bias and , are connected to the input of a second differential amplifier with split closing biasing base resistors. The first and second differential amplifiers have a common current generator, which is repeatedly connected to a common diode through a first diode to a common terminal of the base resistors, and through a second diode connected in the same direction of travel to the first diode as the control input of the controlled current generator. The first differential amplifier has a Voltage input of the first switchable voltage level input, the second differential amplifier has a power input of the second switchable voltage level input. The first differential amplifier manifold has a first switch, the second differential amplifier manifold has a second switch, the first and second switch are transistor shaped, and their transistor collector is connected to each other to form an output of the circuit arrangement.

BACKGROUND OF THE INVENTION The present invention relates to a high-speed, three-state switching circuit arrangement which is mainly used as part of pinelectronics for digital circuit measuring and test automation and for switching voltage levels, particularly programmed logic voltage levels Uh and Ui. The switchgear arrangement of the present invention has controlled current generators and switches for switching voltage level and switching voltage level per 1 input.

Solutions for the design of three-state switching circuits are known which employ two diode quadrants arranged in a Graetz circuit of the same design, switching the logic voltage applied to the ¹ input of each diode quadrature by turning on the third counterclockwise simultaneous shutdown. Such solutions, and the 2240971st ² 1591 999. U.S. Pat. Federal Republic of Germany, and U.S. Patent No. 2,179,242. French patents. The advantage of circuits is the transient-free switching to the third state, but their disadvantage is the overshoot of switching the logic levels caused by the control modulation of the switching diodes. Thus, switching circuits that meet more stringent requirements, especially higher speeds, can only be designed with very expensive diodes, and again only with compromises. A further disadvantage of such circuits is the control 3 (independently of significant dissipation, which is a limitation of application in the case of integrated circuit measuring and testing machines.

Another group of three-state switching circuitry solutions are those that employ a dual-state switching circuit 3i and a series - third - most transistor switch.

The two-state switching circuit, with the serial switch closed, switches the specific voltage levels depending on the control, while the third switches the 4 (state by switching off the serial switch. Such circuitry is used by Fahrchild (USA) SENTRY VII, SENTRY VIII integrated) mérőautomatáiban.

A disadvantage of such a circuit is the high output impedance of the circuit 45, which is the sum of the resistance of the serial switch and the impedance of the signal line. This value is quite high even when the serial switch is placed near the signal application, approx. 60-70 ohms, which limits the maximum output signal slope considering the load capacitance value. Switching to each state can be achieved relatively slowly, and only with significant transients, due to the finite control electrode - main electrode capacity of the transistor implementing the serial switch and the output resistance, depending on the voltage levels to be connected. A typical transient data is the magnitude of the third-order transient, which is 800 mV at 12.5 pF and 10 Mohm. A further disadvantage has been found 60 that the dual-state switching circuit has a voltage generator output and does not have a short-circuit protection, which can result in a failure of the circuit in the event of a short-circuit.

The development of the devices to be measured, the reduction of the measurement time, the extension of the upper frequencies, and the development of high-complexity circuits have made it necessary to develop high-speed three-state switching circuits that operate surge-free, third-state transient, low-power, can also be implemented.

There was also a need for a switching circuit design for adjustable switching voltage levels over a wide range.

A circuit arrangement meeting the above requirements is based on the recognition that a three-state switch can be implemented with a differential amplifier stage, wherein the switch itself is in the collector circuit of the differential amplifier stage, its states are provided by a controllable design of the emitter circuit current generator.

The high-speed switch circuit arrangement which provides the object of the present invention is capable of switching voltage levels, in particular - programmed - logic U _H and U _L voltage levels under control, and of providing an "open" state. The three-state switch circuit arrangement has controlled current generators with switching voltage level input and switching voltage level per input. The circuit arrangement consists of receiving a drive signal receiving stage and a third stage controlling signal receiving stage, the first differential current amplifier having a first controlled current generator and a second differential amplifier having a first controlled current generator and a split, closing bias, and are connected to the input of a second differential amplifier with split closing biasing base resistors, and the first and second differential amplifiers have a common current generator which is repeatedly acting as a common price generator as a differential amplifier on the first diode to the common terminal is connected to the control input of a controlled current generator, the first diffuser a power amplifier input for the first amplifier to be connected, a second differential voltage amplifier for a first switch, a second differential amplifier manifold for the first switch, a second differential amplifier manifold for the second switch, the collectors of their transistors connected to each other form the output of the circuit arrangement.

The three-state switch circuit of the present invention is operable by controlling the drive signal receiving stage and the third-state signal receiving stage. As long as it receives a signal to switch to the third state, the level gear is operated as a current generator. Its output current, through the base resistor of the differential amplifiers, relieves the biasing of the differential amplifiers and provides a reference point current, and through the common member of the base resistors, the first diodes are biased in the closing direction. The common current generator current, through the open second diodes, controls the controlled current generators, which provide differential amplifiers with a daily emitter current. The output current of the leveling gear, on the other hand, controls the first and second differential amplifiers, and thus the transistor saturation switches connected in the collector circuit of the differential amplifiers, countercurrently, according to the control of the drive signal receiving stage. The power supplies for the differential amplifiers are provided by the voltage levels to be switched, so that the voltage levels displayed at the common output of the switches are the same as the voltage levels to be connected,; or less with residual voltage on the switches.

In the case of a signal to switch to the third state, the three-state leveling stage as a current generator is switched off. Thus, at the base of the transistors of the differential amplifiers, the forward bias is applied, the first diode is open and the second diode is biased. Thus, the current j of the common current generator, passing through the first diode, is more forward in the closing direction of the base of the transistors of the differential amplifiers. The current of the controlled current generators is reduced, thus the operating point and emitter currents are reduced to zero, the differential amplifiers are switched off. The connected outputs of the switches in their collector circuits have an indefinite potential: they become floating, showing a "tear" from the output.

Preferably, the first and second controlled current generators have a temperature compensated configuration for the three-state switching circuitry.

The switching circuit according to the invention is further provided; In a slender embodiment, a switch placed in the collector circuit j of each differential amplifier is one! same as another. The first or first. a second switch having a fifth transistor having a base connected to an emitter through a second resistor and to a collector of one transistor of the differential amplifier via a third resistor and to a collector resistor of the second transistor via a fourth transistor across the third transistor the voltage to be connected is connected to an input.

In the preferred embodiment, the phenomenon of front-shot at the output signal, which results from the layer capacity of the output semiconductor devices, is reduced by a first capacitor coupled between the collector of the second transistor of the differential amplifier and the fifth transistor of the saturator.

Maintaining the output's ohmic nature over a wide range is ensured by a second capacitor connected between the collectors of the fifth transistor of the two switches and by connecting these collectors via a fifth resistor. This reduces the effect of the output scattered inductances.

In a further embodiment, the drive signal receiving stage and the third-state controlling signal receiving stage are preferably stages with a counter-current output, and their outputs are wired OR. In a further preferred embodiment, the level transfer stage has a first and a second pair of transistors, and the emitter of the transistors forming one pair is connected to each other through a resistor. The base of one of the transistors of the transistors is connected via a level shift stage to the output of the third stage control signal and the base of the other transistors to the counter-output of the drive signal stage. The collector of one of the transistors is connected to the input of the first differential amplifier and the collector of the other transistors is connected to the input of the second differential amplifier.

The main advantage of the three-state switching circuit according to the invention is that it has a novel design, with lower cost components and more favorable parameters than those of similar circuits, especially at higher operating speeds. The degree of overshoot at switching the definite, most programmed, logic voltage levels is acceptable, while the switching to the third state is negligible, while the switching current is low at the definite states and minimal at the third. The three-state switching circuit of the present invention is well-suited for use as part of the pin-electronics of a complex digital circuit tester.

The present invention will now be described in more detail with reference to a preferred embodiment, with reference to the accompanying schematic diagram, which shows a circuit diagram in part and a more detailed circuit diagram of the switching circuit.

The switching circuit, as shown in the figure, has a drive stage receiving stage 2 and a receiving stage 4 receiving stage, and a level-transmitting stage 6 connected to the output of these receiving stages, which is connected to the first differential amplifier 8 and the second differential amplifier.

The receiving stage is provided with counter-current output and is wired OR connected to each other.

The level 6 has two transistor pairs, where the T1-T2 and / or the transistor pair, respectively, form the pair. The emitter of T3-T4 transistors is connected through a resistor. The base of one of the transistors TI —- Τ2 of the first transistor pair T1 —- Τ2 and of the second transistor T1 and T3 are connected via 5 level shift stages to the output of the third state control signal 4 and the base of the other transistors T2 and T4 .

The collector of transistors T1, T2, T3 and T4 is open, and the collector of one of the transistors T1, T3 of the pair of transistors forms one output pair of level 6 and the collector of other transistors T2, T4.

The first differential amplifier 8 has a forward biasing split base resistor, one of the base resistors being a common member R1, and having a temperature compensated first controlled current generator 10 in its emitter circuit. The power differential input of the first differential amplifier 8 is a first voltage level input U1 to be connected, and one of the transistors has a first transistor 20 in the collector circuit. Similarly, the second differential amplifier 8 'has a biasing biasing base bias in the closing direction, wherein the lower member of the base resistors is a common member R 1' and a temperature controlled second controlled 10 'in its emitter circuit.

-3183 699 is equipped with a current generator. The power supply input of the second differential amplifier 8 'is a second voltage level to be switched and a transistor second switch 20' is located in the collector circuit of one of the transistors.

A collector of one of the transistors Ti and T3 of the level-transmitting stage 6 is connected to the first differential amplifier input 8 and a collector of other transistors T2 and T4 is connected to the second differential amplifier input 8 'so that one transistor containing the first switch 20 its base is connected to the third transistor T3 of one pair of transistors, while the transistor carrying the second switch 20 'in the collector circuit of the second differential amplifier 8' is connected to the second transistor T2 of the other pair of transistors.

The first and second differential amplifiers 8 and 8 'also have a common current generator 16 which, as a differential amplifier, is repeatedly D1 and D1, respectively. Through the first diode Dl 'to the common terminal of the differential resistances of the base amplifiers, on the other hand to the D1 or D1'. D2 and D1 'connected in the same direction as the first diode D1'. It is connected via a second diode D2 'to the input of the controlled current generators.

The first and second and 8 'differential amplifiers, the first and 10' second controlled current generators and the first and second switches 20 and 20 'and the common current generator 16 are connected in similar circuits, the transistors being different due to the opposite voltage supply. and the direction of connection of the diodes.

The first switch 20 and the second switch 20 'have T5 and / or 20, respectively. T5 'has a fifth transistor, which is based on R2 and 2, respectively. R2 'via a second resistor to its emitter and R3 and R3 respectively. R3 'is connected via a third resistor to the collector of one of the transistors of the differential amplifier. Via the fourth diode D4 ', T5 and T5 respectively. T5 'is connected to the collector of a fifth transistor. The collector of the other transistor of each differential amplifier is on the one hand R4 and on the other. Via the collector resistor R4 ', the T5 and T5 respectively. T5 'in combination with the emitter of the fifth transistor D3 and D5 respectively. Via a third diode D3 ', the U _L and / or U diodes to be connected. U ₍₍ is connected to the input of a voltage level and is connected via a first capacitor Cl and Cl 'to the common terminal of the fifth transistor T5 and T5' and the fourth diode D4 or D4 ', respectively.

The first 20 or so. The output of the second switch 20 'is shown in FIG. D4 'fourth diode, Cl. Cl 'first capacitor and T5 and T5 respectively. T5 'is the common terminal of the collector of the fifth transistor.

A second capacitor C2 is connected between the outputs of the first switch 20 and the second switch 20 '. The two outputs are R5 and R5 respectively. R5 ', combined with a fifth resistor, forms the output K of the switching circuit.

During the operation of the switching circuit, the output K outputs a definite logic voltage level U _M or U _{L to} the third state control signal receiving stage with logic level "1" and the drive signal receiving stage 2 to the desired Un or U | voltage level. The signal appearing at the output of the stage receiving the control signal to the third state 4 upon reaching the level transfer stage 6, through the level shift stage 5, the two transistor pairs

It biases one of the transistors TI and T3 into a conductor. The other transistors T2 and T4 of the two pairs of transistors are thus conducting. The magnitude of the current flowing through each pair of transistors depends on the instantaneous control of the drive 2 receiving stage,

The transistor pairs current of one of the transistors T1 and T3 are summed on a common member of the base resistor R1 of the first differential amplifier 8, and the current of the other transistors T2 and T4 are summed on the common member of the base resistor R1 of the second Dl or. The first diode D1 'is biased in the closing direction. Thus, the price of the common current generator 16 today is D2 and D2 respectively. Flowing through the second diode D2 ', the first and second diodes 10 Actuates a second controlled current generator 10 ', thereby providing an emitter current to the differential amplifiers.

Depending on the instantaneous control of the drive signal receiving stage 2, the current of the transistor pair with the higher current at one of the differential amplifiers at the base resistor of one transistor and at the other resistor at the base resistor of the other transistor serves the open base voltage and base current. If the current of the transistor pair T3, T4 is higher, the transistor connected to the first switch 20 in the first differential amplifier 8 will conduct. The collector current, through the third resistor R3 and the second resistor R2, opens the fifth transistor T5, and through the third diode D3 in the open direction 0, the output voltage of the first switch U1 constituting the supply voltage is reduced by the residual voltages. The saturation of the fifth transistor T5 is prevented by the voltage across the third resistor R3 and the quadrature diode D4, and the forward discharge from the capacitance discharge of the fourth diode D4 and the fifth transistor D5 is reduced by the first capacitor C1. Simultaneously, in the second differential amplifier 8 ', the other transistor connected to the collector position R4 is conducting, and the voltage at the output of the second switch 20' is indefinite, the output showing an "open" state.

If the current of the transistor pair T1, T2 is higher, the conductive transistor described inside the differential amplifiers will be closed and the transistor closed will conduct in the same manner as described. Thus, the output of the first switch 20 shows an indefinite state, and the output of the second switch 20 'displays a second level of voltage U _{H to be} reduced by residual voltages.

A second capacitor C2 coupled between the output of the first switch 20 and the second switch 20 'compensates for the spreading inductances by increasing the frequency band in which the output is considered to be ohmic. - R5 and R5 connected to each switch output. Fifth resistor R5 'is used to adjust the output resistance of the switching circuit in a definite state.

When the switching circuit is actuated, if 3 is the output of the third "open" state at output K, the receiving state of control signal 4 in the third state is controlled by logic level "O". Due to the wired OR connection, the control status of the 2 drive signal receiving stages is inert. A: 4 third state control signal receiving stage out-

-4183 699 turns the signal through the 5 level shift stages of the 6 level gears to close one of the transistors TI, T3 of the pair of transistors. As a result, other transistors T2, T4 do not conduct either D1 or D1.

The first diode Dl 'opens, the current of the common current generator 16 is now based on the values of the base resistors R1 and. R1 ', and D2 and D1 respectively. The second diode D2 'closes. The first 10 or the first. The second controlled current generator 10 'is closed, the differential amplifiers are in a non-current state, the first switch 20 and the second switch 20 and thus the output circuit 10 of the switching circuit show an "open" state from its output.

If a voltage is applied from the output to the switching circuit, as in the case of a pin-electronics application, a state of operation is present and the voltage is greater than T5 and / or. Fifth transistor collector T5 'has an open-circuit voltage of 15 bases in the direction of D3 and a closed-circuit voltage of 15 bases. The third diode D3 ensures the "broken" state is maintained.

Claims (6)

Patent claims 1. High-speed, three-state switching circuitry, voltage levels, especially - programs ₂₅ our quantities - logical Un and Ul switching of voltage control and for implementing "open" state, which is controlled by a current generator (10,10 ') voltages (U'; U _L) , input and switching voltage level (U _fl ; U _L ) have ₃₀ switches per input, characterized by a drive signal receiving stage (2) and a third state controlling signal receiving stage (4), which through the level transmitting stage (6) first controlled current source (10) and joint member, split záróira- ₃₅ ser biasing base resistors with the first differential amplifier (8) and emitterkörében va 'second differential amplifier (8 a and common membered shared reverse biasing bázisellenáilásokkal) input of the second controlled current source (IC)' HBVs köt- ve θ _4, the first and the second differenciálerősítőnek (8, 8 ') áramgenerátora joint (16) which is a common current generator (16) repeatedly for each differential amplifier on one hand a first diode (Dl, respectively. DI ') via the base resistors common terminal, on the other hand the El- _4r salt diodes (dl, respectively. DI' are the same) driving direction on through ^J bonded second diode (D2, respectively. D2 ') of the controlled current generator (10 respectively. 10 '), the power input of the first differential amplifier (8) is the first voltage level (U _L ) to be connected, the power input of the second differential amplifier (8') is the second voltage level (U _! ) to be connected, and the first differential amplifier (U) _. 8) a first switch (20) in the collector circuit, a second switch (20 ') in the collector circuit of the second differential amplifier (8'), the first and second switches (20, 20 ') being transistor-shaped and their fifth transistors (T5). , T5 ') collector connected to each other to form the output (K) of the circuit arrangement. An embodiment of a circuit arrangement according to claim 1, characterized in that the first and second controlled current generators (10, 10 ') are temperature compensated. An embodiment of a switching arrangement according to claim 1 or 2, characterized in that the first or second embodiment of the circuit arrangement. a second switch (20, 20 ') having a fifth transistor (T5, T5'), the base of which is via a second resistor (R2, R2 ') to the emitter and a third resistor (R3, R3') to the differential amplifier (8, 8 '). connected to the collector of one transistor and via the fourth diode (D4, D4 ') of this collector to the collector of the fifth transistor (T5, T5'), the collector of the other transistor of the differential amplifier (8, 8 ') (R4, R4') Connected to (T5, T5 ') cmitters, a third diode (D3, D3') is connected to the voltage level (U _L ; Uh) to be connected. An embodiment of a circuit arrangement according to claim 3, characterized in that between the collector of the second transistor of the differential amplifier (8, 8 ') and the collector of the fifth transistor (T5, T5') of the switch (20, 20 ') Cl ') is bound. 5. An embodiment of a switching arrangement according to any one of claims 1 to 5, characterized in that a second capacitor (C2) is connected between the collector of the fifth transistor (T5, T5 ') of the two switches (20, 20') and the collectors are connected through a fifth resistor (R5, R5 '). disfellowshipped. 6. An embodiment of a switching arrangement according to any one of claims 1 to 6, characterized in that the drive signal receiving stage (2) and the third state controlling signal receiving stage (4) are connected to each other with counter-current output and wired to one another; a second pair of transistors (TI, T2; T3, T4), the emitter of one pair of transistors (TI, T2; T3, T4) connected by a resistor, and one of the transistors (TI, T2, T3, T4) of the pair of transistors (TI, T2; Its base T3) is connected to the output of the third stage control signal via a level shift stage (5), and the base of the other transistors (T2, T4) is connected to the counter-current output of the drive signal receiving stage (2). T1, T3) collector for input of first differential amplifier (8) and collector of other transistors (T2, T4) for second differential force <8 '). 1 figure Published by the National Office of Inventions Responsible for publishing: Zoltán Ilimet Head of Department Published by Technical Publisher