NO122067B - - Google Patents

Description

Connection circuit.

The invention relates to switching circuits for use in connection with storage devices for writing and reading information.

Where the term "static, electrical switch" is used in the description and claims, an electronic device is meant which has two transmission electrodes and a control electrode, so that with suitable electrical connections connected to the control electrode, electrical signals can be sent in both directions between signal channels which are connected to the two transmission electrodes.

Examples of static electrical switches include a so-called symmetrical transistor and a cold cathode tube with a single cathode and two anodes as described in English patent no. 734,345. In this type of tube, the cathode acts as a control electrode and the two anodes as transmission electrodes.

In the embodiments of the invention described below, a symmetrical transistor is used. However, it is not necessary (although it may be desirable) that the transistor has identical characteristics in both transmission directions. For this reason, it is preferred to use the term "bidirectional transistor". In each bidirectional transistor, the base electrode acts as a control electrode in the above definition and the other two electrodes (which can be appropriately referred to as emitter electrodes) act as transmission electrodes.

The present invention relates to a switching circuit for use in connection with storage devices for writing and reading information and designed to

to establish a two-way signal transmission path between two sets of power circuits, the signal transmission path being created over two stages with static, electrical switches which in the "on" position can transmit signals in both directions. The invention is distinguished by the fact that each circuit in the first set is connected to an individual switch in the first stage, that each circuit in the second set is connected to an individual group of switches in the second stage, that the switches in the first stage are interconnected in groups each connected to one individual switch in each switch group in the second stage and that control circuits are connected to actuate pairs of switches, one from each stage, to set up a two-way transmission path between any circuit in the first set and any circuit in the other set.

The invention will be described in detail

with reference to the drawings where:

Fig. 1 shows an arrangement for connecting a common write circuit and a common read circuit to any one of a number of heads connected to a magnetic drum. Fig. 2 shows how a two-way transistor switch can be used in a drum storage system of the type shown in fig. 1.

The connection circuit in fig. 1 allows reading by a head from a magnetic drum while simultaneously taking place in- The drum DM is around its periphery writing by another head.

equipped with 16 magnetic read-out

print heads divided into four groups: 11—14, 21—24, 31—34, 41—44. In general, each head will control reading and writing on a special drum track reserved for that head.

Each head in a group is connected via a switch (ie HS11, HS12, HS13 and HS14 for heads 11, 12, 13 and 14) to a write group switch (WGS1) and a read group switch (RGS1) common to all heads in a group group. One and the same write circuit W is connected to all the write group switches WGS1, WGS2, WGS3 and WGS4 and one and the same read amplifier R is connected to all the read group switches RGS1, RGS2, RGS3 and RGS4.

The opening and closing of these switches is controlled by a register which is shown schematically at the bottom of fig. 1. These registers can be any form of distributor such as e.g. relay, gas tube, crystal diode or vacuum tube counter circuits, or other "step by step" devices. The write group register WGX and the read group register RGX have four stages each. Each step in the write group register controls one of the four write group switches WGS1—4, and each step in the read group register controls one of the read group switches RGS1—4. If, for example, the write group register WGX is in position 3, it will supply the write group switch WGS3 with a control voltage so that this switch closes and allows signals to pass from the current circuit W to the head switches HS31—34. If the reading group register RGX is in position 2, in the same way a control voltage will be supplied to the reading group switch RGS2 so that this switch closes and allows signals from the head switches HS21—24 to pass to the reader amplifier R.

The print head register WHX selects in conjunction with the write group register WGX through a gate circuit one of the 16 head switches and applies a control voltage to close the selected head switch, thus connecting the selected head to the write group switch and completing a circuit between the write circuit W and the selected head. Likewise, the read head register RHX in conjunction with the read group register closes the designated head switch to complete the circuit between sense amplifier R and the selected head.

It appears from fig. 1 that only two gate circuits are drawn, namely those connected to head switches HS11 and HS44. This is done to simplify the figure, but it is clear that similar ports are connected to each of the head switches.

The operation of the circuit will be better understood by taking a specific example.

Let it be assumed that it is to be written through head 11 and read from head 44.

To write through head 11, the writing group switch WGS1 and the head switch HS11 must be closed.

The write group register WGX steps up to position 1 and through its control circuit WGX1 the write group switch WGS1 is closed. The print head register WHX is now stepped up to position 1. The gate Gl is opened because both WGX and WHX are in position 1 and closes the head switch HS11 above gate G2. A circuit is now established from the write circuit W across the write group switch WGS1 and the head switch HS11 to the head 11 so that signals can be written onto a track at the head 11.

To establish a reader circuit from the head 44, the reading group register RGX is stepped forward to position 4 so that it closes the reading group switch TGS4. The read head register RHX is also stepped to position 4 so that RHX4 in connection with the already affected RGX4 opens gate G3 and above gate G4 the head switch HS44 closes. In this way, a reader circuit is established from the head 44 above the head switch HS44 and the group switch RGS4 to the reader amplifier R.

It will be seen that by dividing the read/write heads into groups and controlling each group by a separate read and write group switch, it is possible to write through any head in a group and at the same time read from any head in any any of the other groups. In the above-mentioned example, writing can thus be done through head 11 at the same time as reading at head 44 (or in reality at any of the heads 21-44).

Fig. 2 shows how a switch using two bi-directional transistors can be used as write group switches and read group switches in a drum register system of the type described above in connection with fig. 1.

For clarity, only a write group switch WGS1, a read group switch RGS1 and a head switch HS11 are shown in fig. 2. It is clear that the other write group switches and the read group switches each comprise a switch using two identical bi-directional transistors with WGS1 and RGS1 and that all the other head switches comprise a switch using only one bi-directional transistor identical to HS11.

The head switch HS11 uses a bidirectional transistor C which is arranged so that it has two states, an "on" state where its base electrode is at negative voltage in relation to ground and where the impedance between the two emitter electrodes is low and an "off" state where the base electrode is positive in relation to earth, and where the impedance between the two emitter electrodes is high.

The base voltage on transistors C is controlled by a gate circuit comprising six rectifiers MR4-9 and resistors R4 and R5. This gate circuit corresponds to gates G1, G2, G3 and G5 in fig. 1.

The normal state of transistor C is the "off" state. To achieve this, the voltage on the control wires WGX1, WHX1, RGX1 and RHX1 in the gate circuit is positive with respect to ground. Under these conditions, current flows across the control wires through rectifiers MR4, MR5, MR7 and MR8 and through resistors R4 and R5 to 100 V. As rectifiers MR4, 5, 7 and 8 conduct, the voltage on the negative plate of rectifiers MR6 and MR9 is approximately the same as the voltage on the control wires WGX1, WHX1, RGX1 and RHX1. These voltages are chosen so that when rectifiers MR4, 5, 7 and 8 are conducting, rectifiers MR6 and MR9 are biased to their "non-conducting" state so that the voltage at the base electrode of transistor C is the same as the + 12 V power supply except for a small voltage drop across resistor R6.

If it now e.g. is to be written through head 11, both switches WGS1 and HS11 must be switched "on". To do this, as previously explained, the group register WGX is driven to position 1. In this position, a negative voltage is applied to the connection between the rectifiers MR1 and MR2 via the control line WGX1 on the write group switch WGS1. The two bi-directional transistors A and B become conductive and WGS1 opens to allow signals from the write circuit W to pass to the head switch HS11.

The control voltage on the line WGX1 is also supplied to the rectifier MR4 in the gate circuit which controls the head switch HS11 and thereby biases this rectifier to its non-conducting state. Since rectifier MR5 is still conducting, the change in MR4's state will not change the state of rectifier MR6. The print head register WHX is now moved to position 1. In this position, a negative voltage is applied across the control line WHX1 to bias the rectifier MR5 into its non-conducting state. Since the rectifier MR4 is already in its non-conductive state, the voltage on the connection between the rectifier MR6 and the resistor R5 will drop and the rectifier MR6 will become conductive. Current will now flow from the + 12 V power supply through resistor R6, rectifier MR6 and resistor R5 to 100 V. As rectifier MR6 is in its low impedance state, the base electrode of the bidirectional transistor C becomes negative with respect to ground thereby bringing transistor C to its "on" position. The signals from the writing circuit W are now able to pass through the transistor C to the head 11 where they are registered on the drum DM.

Although no protective devices are shown in the figures, it will be clear to those skilled in the art that some protective precautions will normally be provided. It should e.g. a protection circuit is provided to ensure that two circuit breakers in one group cannot be opened at the same time. In a similar way, other circuits will ensure that both the write group switch and the read group switch in one and the same group are not opened at the same time.

Claims (3)

1. Circuitry for use in connection with storage devices for writing and reading information and arranged to establish a two-way signal transmission path between two sets of power circuits, said path being created over two stages of static electrical switches which in the "on" position can transmit signals in both directions, characterized in that each circuit (11—14, 21—24, etc.) in the first set is connected to an individual switch (HS11—HS14, HS21—HS24, etc.) in the first stage, that each circuit (W,R) in the second set is connected to an individual group of switches (WGS1—WGS4, RGS1—RGS4) in the second stage, that the switches in the first stage are interconnected in groups each connected to one individual switch in each switch group in the second stage and that control circuits are connected to actuate pairs of switches, one from each stage, to set up a two-way transmission path between any circuit in the first set and any preferably power circuit in the second set. 2. Connection circuit according to claim 1, characterized in that the second set comprises two current circuits, one of which is a write circuit and the other a read circuit, that the fourth current circuit in the first set comprises the first magnetic read/write head and that a two-way transmission path can be established at the same time between a magnetic head in one group in the first set and the write circuit and between a magnetic head in another group in the first set and the read circuit. 3. Connection circuit according to claim 1 or 2, characterized in that the static electrical switches are bidirectional transistors.