NO158399B - CONTROL SWITCH FOR HIGH-FREQUENCY DIRECTLY SIGNALS. - Google Patents

Abstract

1. A controlled switch for high-frequency signals having no d.c. component comprising in T-formation a series arrangement of a resistor (R2) and a diode (D1) in the first series arm connected to a signal input, a first transistor (T1) in the shunt arm, and a second transistor in the second series arm, where a control voltage can be connected to the base of the first transistor (T1) and the collector of the first transistor (T1) is connected to the diode (D1) and the base of the second transistor (T2), characterised in that the signal input (E) is connected via a first coupling capacitor (C1) to a first and second resistor (R1, R2), that the other terminal of the first resistor is connected to reference potential and the other terminal of the second resistor is connected via the diode (D1) to the collector of the first transistor (T1) and via a third resistor (R3) to a supply voltage (+Ub), that the base of the first transistor (T1) is connected via a fourth resistor (R4) to the supply voltage (+Ub) and via a control switch (S1) to reference potential, that the collector of the second transistor (T2) is connected to the supply voltage (+Ub) and the emitter of this transistor ist connected via a fifth resistor (R5) to reference potential and possibly via a further coupling capacitor (C2) to the output terminal (A), and that the diode (D1) consists of a PIN-diode.

Description

The invention relates to a controlled switch for high-frequency direct current-free signals, made in T-shape with a series connection of a resistance and a diode connected to the signal input in the first longitudinal branch, with a first transistor in the transverse branch and with a second transistor in the second longitudinal branch, where a control voltage can appear on the first transistor's base connection and the first transistor's collector connection is connected to the diode and to the second transistor's base connection.

Within connection technology, it is often necessary to enter or disconnect or switch high-frequency signals, which are, however, free of direct current. Thus, e.g. in the information measurement technique, switches with which a measuring instrument can be connected to an information transmission line without the signal to be examined being falsified thereby. Also in the case of information transfer,

is it necessary to use switching devices that make it possible to switch from a disturbed to an undisturbed transmission line. Such switches are often realized with two controlled switches, one of which switches on and the other off.

An input switch designed for three input signals of different frequency and made up of three emitter-coupled difference amplifiers is known from the "Hewlett-Packard-Journal", February

1981, page 13, fig. 3.

From DE-A-24 36 255, there is already known a similarly T-shaped controlled switch for high-frequency direct current-free signals. This controlled switch contains in the first longitudinal branch

a series connection of a resistor and a diode connected to a signal input, in the transverse branch a first transistor and in another longitudinal branch another transistor which, together with at least one further transistor and with the series connection of resistor and diode, forms a negative resistance. This negative resistance is idle-stable and can be controlled, and supply and output of the signals

takes place via transformers.

For controlled switches of the kind mentioned at the outset

a number of demands were made there. With a view to application in the transmission of broadband signals with frequencies such as those occurring in the 140 Mbit/s digital transmission system, a high reflection attenuation at the switch input is required in each switching state. A high-quality signal transmission requires small

non-linear distortions when the signal is passed through re-

nom the switch, although there because the use of amplifiers can cause attenuation of the signals on the way through the switch. With regard to the application that switches in information transmission lines, it is also required for such controlled switches that, in addition to a short switching time of less than 1 ms, there must be a high barrier damping in the disconnected state over a wide frequency range. With a view to the use of such switches in places in information transmission lines that are not easily accessible, great reliability is required, which in turn makes a small connection technical expense particularly desirable, and finally it is required that the switch is disconnected from subsequent devices.

The task of the invention therefore consists in making it possible

to make a switch of the type mentioned at the outset so that it meets the enumerated requirements.

According to the invention, the task is solved by

- that a first and a second resistor are connected to the signal input via a first coupling capacitor,

- that the second connection of the first resistor is connected

with reference potential and the second resistor's other connection is connected to the first transistor's collector connection via the diode and to a supply voltage via a third resistor,

- that the base connection of the first transistor is connected

with the supply voltage via a fourth resistor and with reference potential via a control switch, - that the second transistor's collector connection is connected to the supply voltage and this transistor's emitter connection via a fifth resistor is connected to the reference potential and possibly via an additional coupling capacitor with the output connection,

- and that a PIN diode is arranged as a diode.

In the switch according to the invention, the requirements for high blocking damping and disconnection of the subsequent devices are met in a particularly advantageous way with little switching technical expense and little load on the components used, and advantageously only a single operating voltage is also required.

With a view to the use of only one control switch resp.

only one control signal, an appropriate further development of the invention consists in the connection of the control switch being connected to the base connection of a third transistor, this third transistor's emitter connection to a reference potential and its collector connection to the first transistor's base connection.

Due to the short switching time of approximately 1 jas at the stated switch, this is particularly advantageously applicable as an input switch in a transmission system for digital signals.

The invention will be explained in more detail below with reference to the drawing.

Fig. 1 shows the connection diagram for a controlled switch according to the invention, and

fig. 2 shows the circuit diagram for a switch according to the invention containing two controlled switches in accordance with fig. 1.

The controlled switch shown in fig. 1, has a signal input E, and to this a first and a second resistance Ri and R2 respectively are connected via a first coupling capacitor Cl. While the second connection to the first resistance Ri

is connected to reference potential, the other connection to another resistor R2 is via a PIN diode Dl connected to the collector connection of a first transistor Tl and to the base connection of the second transistor T2. The emitter connection of the first transistor Tl is connected to reference potential, and this transistor's base connection is via a fourth resistor R4 connected to operating voltage +Ub and also via a first control switch Sl with reference potential. The base connection to the second transistor T2

is via a third resistor R3 connected to operating voltage +Ub, and with the base connection the collector connection of the second transistor T2 is also directly connected. The emitter connection of this transistor is connected to the reference potential via a fifth resistor R5 and to the signal output via another coupling capacitor C2.

The controlled switch is structured like a T-joint with two disconnectors in the longitudinal branch and one disconnector in the transverse branch. The first resistor Ri serves in this connection to adapt the line and thus to increase the reflection damping

regardless of the respective switching state. The resistor R4

forms together with the pin diode Dl polarized in the slip-through direction and the third resistor R3 a voltage divider for the input signals, at the same time that the transfer characteristic of the PIN diode is linearized with the resistor R2. The output stage of the controlled switch with the transistor T2 is arranged in emitter-follower connection. Thanks to the non-shunted resistor R5, a negative feedback is obtained for linearizing the emitter

the follower's transmission characteristics. The disconnector in the first longitudinal

branch of the T-switch is thus realized with the PIN diode D<i>f while the emitter follower in the transistor T2 forms the disconnector in the T-switch's other longitudinal branch. The disconnector in the T-switch's cross-

branch is realized with the transistor Tl.

The control of all the individual disconnectors takes place via a first control switch Sl which, in the switched-on state, connects the base connection of the first transistor Tl with reference potential. Thus, in this case it occurs at the collector connection

to the transistor Tl a maximum collector voltage, while the transistor Tl in the second position of the first control switch Sl is controlled to saturation and thus almost forms a short-

conclusion for the remaining signals that emerge above the capacity of the now de-energized, i.e. blocked, PIN diode.

The controlled switch according to the invention can of course also be realized with complementary transistors and repolarized PIN diode as well as negative operating voltage. In addition, reference potentials and operating voltage can be exchanged.

The switch in fig. 2 is arranged as an input switch

for a digital transmission system with a bitrate of 140 Mbit/s.

For this purpose, two controlled switches according to fig. 1 connected together on its output side. A first controlled switch is connected to a first input El, which, in connection with a coupling capacitor Cll connected to the input, exhibits a parallel connection of two resistors. One resistor R1 is connected to the reference potential and serves as line termination, while the other resistor R12 serves to linearize the PIN diode D11, which is connected via a further coupling capacitor C12.

A pair of diodes D12, D13 in anti-parallel connection is also connected to the diode-side end of the resistor R12, whose other connections are connected to the reference potential, and which, together with the resistor R12, act as fine lightning protection.

For termination of the direct current path there is to the connection between the additional coupling capacitor C12 and the PIN diode

Dll connected a resistor R15 whose other connection is connected to reference potential. The anode of the PIN diode Dll is connected to the collector connection of a transistor T1, with a connection to a resistor R13 and to a connection to a resistor R16 whose other connection is connected to the base connection of a further transistor T12. The emitter connection of the transistor Til is connected to the reference potential, while the base connection of this transistor is connected to a control switch S2 across a resistor R14 and to operating voltage +Ub across a resistor R18. Another connection to the resistor R13, the collector connection to the transistor T12 and a filtering capacitor C13 are also connected to the operating voltage +Ub. The emitter connection to the transistor T12 is via a parallel connection acting as a correction link of a series resonant circuit RS and a resistor R17 connected to a further coupling capacitor C14 and also via a further resistor R18 with reference potential. An amplifier VI is connected to the capacitor C14, whose output connection forms the switch's output connection A.

A further controlled switch is connected to the second input E2 of the switch, which is constructed just like the controlled switch connected to the input El, and likewise to its output is connected the correction link RS, R17, R18. For phase rotation, only in the connection from the controlled switch to the transistor T21, in addition to a resistor R27, a transistor T23 is added whose base connection is connected to the resistor R27, whose emitter connection is connected to the reference potential, and whose collector connection is connected to the base connection of the transistor T21, which corresponds to the transistor To.

The other connection to control switch S2 is connected to reference potential. When the switch is open, the signal path from input E2 through the controlled switch to output A is released,

while the signal path from the input El over the lower controlled switch to the output A is released when switch S2 is closed. The function of the two controlled switches is exactly the same as for the controlled switch in fig. 1,

and with a view to distortion correction of the cable leading to the inputs, a correction link with a slip-through attenuation of approx. 12 dB. This correction link consists of the parallel connection of the series resonant circuit tuned to a frequency of approx. 130 MHz and the voltage divider formed by resistor R17 and resistor R18.

When connecting additional controlled switches in parallel, there can

in analogy with the switch in fig. 2 also build up a multi-

plexes for a larger number of n input signals.

Claims (2)

1. Controlled switch for high-frequency direct current-free signals, made in T-shape with a series connection of a resistance and a diode connected to the signal input in the first longitudinal branch, with a first transistor in the transverse branch and with a second transistor in the second longitudinal branch, where on the first transistor's base connection can act as a control voltage and the first transistor's collector connection is connected to the diode and to the second transistor's base connection, characterized by that a first and a second resistor (RI, R2) are connected to the signal input (E) via a first coupling capacitor (Cl), that the second connection of the first resistor is connected to the reference potential and the other connection of the second resistor is connected to the collector connection of the first transistor (Tl) via the diode (Dl) and to a supply voltage (+Ub) via a third resistor (R3), that the base connection of the first transistor (Tl) is connected to the supply voltage (+Ub) via a fourth resistor (R4) and to the reference potential via a control switch (Sl), that the collector connection of the second transistor (T2) is connected to the supply voltage (+Ub) and its emitter connection is connected to the reference potential via a fifth resistor (R5) and possibly via a further coupling capacitor (C2) with the output connection (A), and that a PIN diode is arranged as diode (Dl). 2. Controlled switch as specified in claim 1, characterized in that the connection of the control switch (Sl) is connected to the base connection of a third transistor, that the emitter connection of the third transistor is connected to the reference potential, and that the collector connection of this transistor is connected to the base connection of the first transistor (Tl ).