DE2039710B2 - Power supply for digital telephone exchange - has reserve circuit switches located behind smoothing capacitors to speed switch on - Google Patents

Abstract

The power supply, for a digital telephone exchange, supplies reserve units and circuits that are partly or wholly switched off and brought up to full operational readiness in the shortest possible time without supplying these partly-off of wholly-off circuits with unacceptable large currents. The power supply (Q) for the continuously-on units and circuits (K') (e.g. connection switching memories) is connected directly to the smoothing capacitors (C) that serve the partly or wholly off circuits when the latter are switched in. The switches (S1,S2) that connect in these circuits are located after the smoothing capacitors.

Description

25th

The invention relates to a circuit arrangement according to the preamble of the patent claim.

It is known to use conventional relay circuits which process digital signals, in particular public ones Telephony switching systems to be set up in such a way that their parts even in the standby state little Consume power loss.

Also for circuit arrangements for power supply, in which a source for supplying power to a plurality of circuits each containing semiconductors is provided, various measures are already taken to reduce the often very high power loss known:

In Frequency Band 19, 1965, pp. 386 to 392 are circuit arrangements for power supply of Circuits described. Some of the circuits provided are in themselves with a voltage supply or conductive, so that they would then consume a certain power loss. To reduce Two types of switch-on states are provided for the power loss, namely the standby state and the operating status, the duration of the standby country being significantly longer than the duration the operating state can be. Both states differ in that they are in the standby state the power dissipation-consuming circuits are not connected to the source, while im Operating state these power dissipation consuming circuits are connected to the source. As a result, a consumption of power loss can largely be avoided in these circuit arrangements will.

Also by the DT-AS 13 00 969, column 1, line 43 bis 62 is known that to reduce the power loss consumption in electronic circuit arrangements with a source for power supply from here Circuits formed by electric circuits provided the measure to keep the source in the standby state to be switched off completely, but to be connected to all circuitry when in operation. Here it is too possible that the standby state lasts much longer than the operating state. These

⁷¹⁰ I> measure, however, often leads to the fact that undesirably long periods of time are required to restore the operating state in which the useful signals can be applied. Obviously, this is particularly troublesome in the case of circuit arrangements which contain a large number of electronic components and which contain logic elements.

In the quoted DT-AS 13 00 969 it is stated that complementary transistors can also be provided to reduce the power loss consumption of digital signal processing circuits, namely in the case of flip-flops, that is to say in the case of certain electrical memories. However, this generally requires a relatively high level of circuit engineering complexity, and moreover it is evident, especially in systems containing a large number of components, that this measure cannot always be easily selected, especially when conventional semiconductor chips available on the market are to be used for their construction; In general, these chips do not contain complementary transistors which avoid such power losses.

Miniaturization is also a frequently used one that processes power loss into digital signals Circuit-reducing measure, which is generally applied in addition to the above-mentioned measures can be. However, it is known that the power loss due to miniaturization is often only can be reduced in an unsatisfactory manner. The individual miniaturized components consume in spite of clever dimensioning and construction only little power loss. The often very high number of however, the total number of components contained in such an electronic circuit corresponds to a very high level Power loss consumption.

In the quoted DT-AS 13 00 969, in particular from column 3, line 20, the power loss in Circuits processing digital signals, in particular in electrical memories such as flip-flops, by means of electronic circuitry having a source for supplying power to a plurality of each Semiconductors containing circuits formed by electrical circuits to reduce, with a considerable here Load circuits or load current circuits are part of the circuits and are supplied with power Power dissipation would consume and being the standby states, during which only a part of these circuits are connected to the source, much longer than the operating states last. There the measure is specified that the load current circuits consuming the power loss, as far as they are conductively controlled in the standby state, only to be connected to the source in the operating state and to connect the other circuits permanently, i.e. also in the standby state, to the source.

The invention was developed for a public electronically controlled telephone exchange, the parts of which should consume little power loss in standby mode. Research showed that the measure specified in DT-AS 13 00 969, column 3, line 20ff to reduce the power loss z. B. in such switching systems is often not sufficient because of serious disruptions of the Operation, namely z. B. incorrect connections can occur. It is precisely with such an extensive System that has a large number of heat-sensitive semiconductor circuits containing the Power dissipation usually not only

because of their height probe; η is also particularly unpleasant because of its influence on the reliability of the system. The disturbances that occur also consist in the fact that in many places in the system pulses and Pulse trains with incorrect information content occur, which is what happens when processing digital signals Switching is not permitted.

In the case of the aforementioned network system, the other known measure is also to reduce losses It is not permitted to switch off the source completely during the standby time and to connect it to the circuits during the operating time; it kicked namely initially also disturbances. It therefore had to be a new technical teaching to reduce the Power dissipation developed for a telephone switching system without impairing the reliability that processes digital signals. This involved comparatively surprisingly little effort Requiring new teaching set up, soft is also generally suitable for other circuit arrangements

The invention is based on the object, the periods of time required to restore the operating state the circuit arrangement mentioned in the preamble of claim are required, if possible To make it short, without unpleasant the power consumption of the system parts that do not require constant power to increase. This brevity in particular avoids faults in the system that by reaching the full voltages or currents required to operate the system too slowly be evoked.

This problem was solved by the measure mentioned in the characterizing part of the patent claim.

In the invention, in fact, interference is avoided in circuit arrangements according to the The preamble of the claim occurs when, in accordance with the teaching of DT-AS 13 00 969, the for the storage of entered information serving load circuits of electrical storage all without exception during the standby state, during which only some of the circuits are connected connected to the source are not connected to the source. One constructed according to the invention The circuit no longer shows such malfunctions, although only during the standby state comparatively little power loss is consumed.

The system parts that are constantly supplied with power are in particular electrical storage devices, z. B. to ring counters, flip-flops and shift registers. Such memories often contain additional components, such as an input amplifier or input pulse shaper, which are used to input information. These Additional parts of the memory are considered in the following as parts of this memory and therefore no longer specifically mentioned. - · Electrical memories generally have to be used for storing entered data Information is constantly supplied with power, otherwise the information would be lost, which is why such memories are then connected to a power supply source. Those associated with a source electrical storage devices are widely used, not only in circuits that have only a few components but also in circuits containing a large number of components such as digital computers and public Telephone switching systems. The ones in electric Storage circuits contained therein have various known advantages such as their miniaturisers harshness. but they often contain many load circuits, which consume power loss in the conductive state.

The invention is particularly suitable for maniaturized circuits in large systems in which the high consumption of power dissipation is often particularly troublesome.

An exemplary embodiment of the invention is shown in the drawing. The circuits to be supplied with electricity are essentially divided into two groups, namely the relatively large group K and the relatively small group K '.

The latter contains each - in general comparatively only a few - circuits, which the electrical storage 5p - z. B. flip-flops, shift registers and ring counters - which are used to store information entered outside and / or during standby time and which consume electricity to enter and store this information. In addition, the group K ' contains those circuits St which, when acted upon by a control signal generated within the circuit arrangement and supplied from outside the circuit arrangement, trigger the switchover from the standby state to the operating state only when a current is supplied.

Group K includes circuits containing semiconductors that do not contain the above-mentioned electrical storage devices 5p and switching circuits St. In a public telephone exchange, the group K z. B. all or a substantial part of the route finding devices, setting devices, monitoring devices and signaling devices. The source Q is used here to supply power to the plurality of circuits, each containing semiconductors, which belong to both group K 'and group K.

According to the technical teaching of the invention, the group K ' is connected to a source Q via the lines 1 not only during the operating state of the circuit arrangement but also during the standby state of the same. In the switched-on state of the circuit, the source Q is therefore connected via the lines 1 only to the circuits contained in the group ^ 'even during the standby state. The circuits belonging to group K are separated from the source Q via switches 51 and 52 during the standby state. During the operating state, the switch 52 is conductive. In addition, the switch 51 can be conductive. Then the circuits contained in group K are connected to a source Q serving for the power supply, namely at least the circuits to be supplied with smoothed direct voltage to the output R of the device C, C. This switch 52 - here also the switch 51 - is through one - or if several are provided, by one of the several - switchover circuits 5 /, which trigger the switchover from the standby state to the operating state when a control signal is applied, directly controlled, as indicated in the drawing.

In the embodiment shown in the drawing it is achieved by appropriate control of the switches 51 and 52 that during the standby state, by controlling these switches in the non-conductive state, only the circuits of group K 'are connected to a source and that during the operating state By controlling this switch in the conductive state, the circuits are also switched on

of group K are connected to a source. If in a system containing a large number of semiconductor circuits, in particular in a telephony switching system, part of the system is in the operating state and the rest in the standby state, then all advantages of the invention act within the standby state by applying the invention to the part that is in the standby state this part to the full.

Particularly small losses can often be achieved in that, during the standby time, only those circuits which contain electrical storage devices for storage from outside and / or during the standby time and use electricity to input and store this information, as well as, if available, also Circuits which, when a control signal is applied, trigger the switchover from the standby state to the operating state, are connected to a source. In this case, the remaining circuits are assigned to group K and are only connected to a source during the operating time. This measure is particularly suitable for systems which are relatively insensitive to voltage fluctuations of the source Q. The low losses are based on the fact that group K includes all circuits that do not necessarily have to be continuously supplied with current, but would contribute to a consumption of power loss if connected to a source.

The group K / also includes the device C, C, which contains one or more smoothing capacitors and is already connected to a source in the standby state. In the drawing, a second device containing smoothing capacitors C is shown, which is also connected to the source Q in the standby state. In the exemplary embodiment shown, the period of time required for switching from the standby state to the operating state can be made particularly short, since the relevant smoothing capacitors are already charged to a bias voltage. In this exemplary embodiment, a more rapid restoration of the operating state, which is advantageous for many purposes, can be achieved than if these smoothing capacitors were not charged to this bias voltage during the standby time. In this case, all essential parts of the device, in particular the smoothing capacitors, are already connected to the source in the standby state. Such a design is shown in the drawing.There is a circuit which is supplied with current via the smoothing capacitors C and contains the resistor R , which is connected to the source Q in the standby state, this source at least approximating the charging of the smoothing capacitors C. their required in the operating state operating voltage causes composed of this resistor R in this embodiment, thus, the smoothing capacitors are not only absolutely already charged to a bias voltage, but - namely by means of the resistor R - at least approximately straight to that operating voltage, on soft these smoothing capacitors C during the operating state the circuit arrangement should be charged. Since the smoothing capacitors C are at least approximately already charged to their operating voltage here, this “training” is particularly advantageous for systems that are sensitive to fluctuations in the supply voltage. In addition, this training has the often very important advantage that the time to switch from readiness! s state can be made extremely short to the operating state. The last-mentioned advantage is of particular importance when the occurrence and duration of the standby states obey static laws, i.e. when the switchover to the operating state has to take place spontaneously without prior notice. In this case, a power supply current to the circuits belonging to group K flows immediately and reliably with the amplitude that is provided for the function of the circuits belonging to group K via the switch 5 2, which is switched to the conductive state at the beginning of the operating state . For this purpose, in the embodiment shown in the drawing, the switch 52 is provided which, during the standby time, disconnects from its source Q all those circuits which are supplied with power via the smoothing capacitors and which do not contribute significantly to the charging of the smoothing capacitors C to their operating voltage. By inserting the switch 52, those circuits which are supplied with power in the operating state via the smoothing capacitors C and which do not contribute significantly to the charging of the smoothing capacitors C to their operating voltage are assigned to the group K of circuits, so to speak, which are only supplied with power in their operating state , whereby particularly small losses are achieved with extremely short periods of time to switch from the standby mode to the operating mode.

In the invention it can be provided in each case that several or all sources are combined into a single source unit. Such a measure is shown in the drawing. This is because only a single source Q is specified there, which supplies all the circuits of the circuit with current in the operating state. The source shown in the drawing thus represents a single source unit, which here supplies the entire system with electricity. Because only a single source unit is provided instead of many individual sources, in addition to reducing the number of sources, it is also advantageously possible to reduce the number of switches which cause the switchover from the standby state to the operating state. Thus, in the exemplary embodiment shown in the drawing, the fact that only a single source unit Q is provided ensures that the switchover can be effected by the switches 51 and 52 alone.

Instead of providing special switches for switching from the standby mode to the operating mode, i.e. instead of providing the switches 51 and 52 shown in the drawing, it is basically also possible to use switches that are already in the circuits in groups K and / l 'for others Purposes, e.g. for the implementation of logic functions, are intended to be used for the switchover. Such joint use can save switches provided specifically for switching, such as switches 51 and 52 shown in the drawing.

1 sheet of drawings

Claims (1)

20th Claim: Circuit arrangement for the power supply of a digital signal processing system, the individual parts of which have to be constantly supplied with power in the operating state and are at least partially switched off in the standby state, in particular an electrical telephone switching system, characterized in that in addition to the parts (K '; memory Sp to prepare through-connections) of the system also the device containing at least one smoothing capacitor (C, C) , which is used to supply the parts (K) of the system that do not constantly require current with smoothed direct voltage, is constantly connected to the power source (Q) and in that control switching means (St, 51, S 2) responding to a control signal, the parts (K) of the system which are switched off in the standby state to the output (R) of the device containing these smoothing capacitors (C, C) or to the power source