DE2422285B1 - Circuit arrangement for the uninterruptible emergency power supply of semiconductor memories - Google Patents

Description

The decoupling diode n3 prevents a current flow via the driver and decoding stage 2. Another decoupling diode nl prevents a current from Output of the emergency power regulator Y 1 via the potential Pl and a - not shown - Logic connected between Pl and mass M for the negative coating of Accumulator 4.

A comparator Y3 compares the respective supply voltage of the PMOS memory 1 with an adjustable threshold voltage U4 falls below the If the supply voltage of the PMOS memory 1 exceeds the threshold voltage, a relay drops D from. With the relay contact, a lamp L is controlled, which is the case with an existing one correct operational supply voltage lights up. The lamp goes out L therefore indicates that the supply voltage of the PMOS memory 1 is below the threshold voltage U4 has dropped. The relay D is designed so that its required response value is not reached when the operational supply voltage returns. The comparator Y3 only supplies the holding current. Just by pressing a - ~ button, not shown, can bring the relay D back into the monitoring position will.

One embodiment of the invention provides that the accumulator 4 one connected from a positive potential P2 of, for example, +24 volts Charge controller Y2 is assigned, which compares the charging voltage with a target voltage U2, which can be bridged by a transistor Tr as a controllable electronic component is that of another, to the negative potential N of the operational supply voltage related reference voltage U3 is controlled by the transistor Tr is the charging voltage of Accumulator 4 is held at zero until the potential N of the supply voltage is more negative than the voltage at the output of the emergency current regulator Y1.

This circuit arrangement enables the individual to be switched on and off Allows potentials of the supply voltage in any order. Without that Transistor Tr would be the positive supply voltage of the emergency regulator Y1 from positive coating of the accumulator 4 rise when first the positive potentials Pl and P2 of the supply voltage and only then the negative potential N is switched on would. The negative potential N of the supply voltage would then be smaller than that Output voltage of the emergency power regulator Yl and would cause a voltage drop. The output of the emergency power controller Y1 would be positive to ground M Die between the Potentials Pl and M switched on logic would load the emergency power controller Yl so much, that this goes into current limitation and its output voltage at ground potential remain. The emergency power regulator Yl could no longer work and the voltage between Pl and N are no longer on the for the safe preservation of the stored information hold required value. However, the transistor Tr holds the output voltage of the Charge controller Y2 to ground potential until the negative potential N of Has built up supply voltage.

Claims (1)

Claims: 1. Circuit arrangement for uninterruptible Emergency power supply of semiconductor storage, especially PMOS storage with separate Power supply for driver stage and memory matrix, by means of one of the operational Supply voltage connected in parallel accumulator, d a - characterized by, that the accumulator (4) with the supply voltage connections (la to 1a) of the Semiconductor memory (1) via an emergency power regulator (Y 1) is connected to the respective Supply voltage with an adjustable, compared to the operational supply voltage reduced reference voltage {U 1), and that a decoupling diode (n3) in the reverse direction of the emergency power between the supply voltage connections (1a, ib) the driver stage (2) and the accumulator (4) and another decoupling diode (nl) connected in the reverse direction of the emergency power between the accumulator (4) and earth (M) 2. Circuit arrangement according to claim 1, characterized in that the accumulator A charge controller (Y2> connected to a positive potential (P2) is assigned that compares the charging voltage with a target voltage (U2), which is provided by a controllable electronic component (Tr) can be bridged by another, related to the negative potential (A () of the operational supply voltage Reference voltage (U3) is controlled. 3. Circuit arrangement according to claim l, characterized by a Comparator (Y3) for comparing the respective supply voltage with a threshold voltage (U4), which controls a display device (L) that shows a drop in the supply voltage below the threshold voltage (U4) even after the supply voltage has returned indicates its operational value. The invention relates to a circuit arrangement for the uninterruptible emergency power supply of semiconductor memories, in particular PMOS memories, with separate power supply for driver stage and memory matrix, by means of an accumulator connected in parallel to the operational supply voltage. In the case of semiconductor memories, this means an interruption in their supply voltage the loss of the stored information. It must therefore be uninterrupted Power supply must be ensured. It is the object of the present invention to provide a circuit arrangement for the uninterrupted emergency power supply of semiconductor memories of the input called type that makes it possible to use the information stored about to get a long period of time and to do this only one accumulator with smaller Capacity required. According to the invention, this object is achieved by a circuit arrangement solved, in which the accumulator with the supply voltage connections of the semiconductor memory is connected via a charge controller, which the respective supply voltage with a adjustable compared to the operational supply voltage reduced reference voltage compares, and that a decoupling diode in the reverse direction of the emergency power between the supply voltage connections of the driver stage and the accumulator and a Another decoupling diode in the reverse direction of the emergency power between the accumulator and ground is connected The invention assumes that in emergency operation a The driver and decoder stages of a semiconductor memory do not need to be supplied The voltage supply for the driver and decoder stages is therefore in emergency mode set. In addition, the supply voltage of the memory matrix is reduced to a lower value, for example only half of the operational Supply voltage can be. In emergency operation is therefore in the invention Circuit arrangement for maintaining a stored information only by about an order of magnitude less electrical power is required than in normal operation. The transition from normal operation to emergency operation and back to normal operation takes place automatically, without interruption and without switching operations. An embodiment of the invention and its in the dependent claims Embodiments characterized in more detail is shown in the drawing and is described in more detail below. The voltage specifications selected are only exemplary to understand and do not provide any dimensioning requirements necessary for the invention represent. A PMOS memory 1 contains a driver and decoder stage (buffer) 2 and a memory matrix 3. In normal operation, the PMOS memory 1 from a positive potential Pl of, for example, + 5 volts and a negative potential N of -9 volts across the supply voltage connections la, lb or le, ld The driver stage 2 and the memory matrix 3 are in normal operation therefore the same supply voltage of 14 volts Accumulator 4 is provided, which has a positive potential via a charge controller Y2 P2 is charged from +24 volts. The charging current flows from the charge controller Y2 via the Accumulator 4 and the decoupling diode nl to ground M after reaching the charging voltage the charging current goes to zero. The decoupling diode n2 prevents the flow of the Charging current to the negative supply potential N. An emergency power regulator Yl compares the potential Pl of the supply voltage with an adjustable, compared to the operational supply voltage reduced reference voltage U 1. This reference voltage can be, for example, + 7 volts. the The voltage supply of the emergency current regulator Y1 is between the output of the charge regulator Y2 and the negative potential N. As long as the operational supply voltage is between the potentials Pl and N is present, the emergency power controller Y 1 remains blocked because the The voltage between P 1 and N is greater than the controller output voltage with respect to N. In the case of emergency operation, the supply voltages Pl and As well as P2 drop down to zero. The emergency power regulator Yl takes over the supply of the storage matrix 3.