DE3508648A1 - Device for saving data in a RAM of a microcomputer - Google Patents

Abstract

The device is used for saving data in a RAM of a microcomputer which is connected to a voltage source. The device has an energy store which is connected to the microcomputer via a stabilisation stage and bypasses a voltage dip in the voltage source. The stabilisation stage is controlled by an electronic voltage failure detector which is connected to the voltage source and outputs a switching signal to the stabilisation stage during a voltage dip. As a result, the stabilisation stage is opened and releases the passage of voltage from the energy stored to the RAM. As a result, the voltage required for bypassing the voltage dip can be supplied to the RAM from the energy store. Since the energy store is not connected to the RAM during normal operation, it is ensured that it is capable of outputting sufficient voltage for voltage bypassing during a voltage dip. The data saved in the RAM are retained as a consequence so that the microcomputer can correctly continue to operate after the voltage dip has been eliminated.

Description

Device for backing up data in one

Microcomputer RAM The invention relates to a device for backing up data in a RAM of a microcomputer according to the generic term of Claim 1.

Microcomputer with a RAM, i.e. a read-write memory, are used in radios, televisions, video recorders, heating controls and the like used. Data entered by the user is stored in the RAM of the microcomputer, with which certain operating states of the respective device are programmed can. The microcomputer is operated via the power grid. It keeps coming back before that voltage drops occur in the power grid, for example due to lightning strikes, by short circuits on the high-voltage lines, by a failure in the power plant and the same. The voltage dips are usually very short. For this time but the voltage drop must be bridged by the energy store, otherwise the data stored in the RAM are deleted and thus lost. As energy storage batteries or accumulators are known to cause a voltage drop in the power grid for a short time can bridge. However, batteries only have a limited lifespan, so that it happens that in an emergency the voltage dip is not bridged and the data stored in RAM is lost. The batteries or accumulators are constantly on and constantly supplying power to the RAM.

The invention is based on the object of the generic device designed in such a way that, without the energy store constantly supplying the RAM with voltage, A short-term voltage drop after the microcomputer has been in operation for a long time can be bridged reliably.

This object is achieved in the device of the generic type according to the invention solved with the characterizing features of claim 1.

In the device according to the invention, the electronic voltage failure detector switches the connection between the energy storage and the RAM of the microcomputer. As long as If there is sufficient voltage, the energy store is blocked by the power failure detector separated from the RAM. However, as soon as the operating voltage falls below a specified value drops, the electronic power failure detector still generates the switching signal before the tension collapses completely. The voltage level is determined by the switching signal opened, so that the voltage required to bridge the voltage drop can be fed from the energy store to the RAM. Since the energy storage is at is not connected to the RAM during normal operation, it is assured that it is in can deliver sufficient voltage to bridge the voltage in the event of a voltage drop. The data stored in the RAM are retained, so that after the Voltage drop of the Continue working properly with the microcomputer can.

Further features of the invention emerge from the further claims, the description and the drawings.

The invention is illustrated by means of one in the drawings Embodiment explained in more detail. 1 shows in a block diagram the basic structure of the device according to the invention, FIG. 2 the circuit diagram the device according to the invention.

A microcomputer 1 (Fig. 1) with a RAM has an input 2, an to which a stabilization stage 3 is connected. It is powered by an electronic Voltage failure detector 4 controlled, in the event of a voltage drop in the power grid sends a switching signal to the stabilization stage 3. An energy store 5, the preferably has an electrolytic capacitor is above the stabilization stage 3 connected to the microcomputer 1.

The RAM of the microcomputer 1 stores data that the user into the respective device. When the power goes out and there is no provision for you If emergency power is hit, the data in the RAM are deleted. It is then necessary to re-enter the data. The device ensures that with a Voltage drop in the internal RAM of the microcomputer 1 with electricity provided before the tension collapses. The voltage failure detector 4 monitors the voltage of the respective voltage source. He is designed so that he then a Sends switching signal to stabilization stage 3 when the voltage of the voltage source drops below a specified value. Normally the stabilization level is 3 closed, so that no voltage from the energy store 5 to the microcomputer 1 is delivered.

However, as soon as the power failure detector 4 receives the switching signal If the voltage drops below the specified value, the stabilization stage opens 3, so that the RAM of the microcomputer 1 from the energy store 5 with the required Voltage or with the required quiescent current is supplied. The processes are running so quickly that the voltage from the energy store 5 is already released, before the tension collapses completely. The stabilization level 3 ensures that the voltage is delivered in a level required for the microcomputer 1 will. Stabilization level 3 ensures a stabilized tension level, so that the voltage at input 2 is at the required level. Voltage drops can be caused, for example, by lightning strikes, by short circuits on high-voltage lines, occur due to failure of a power plant and the like. Usually these will Voltage drops are immediately canceled, but the short time of the voltage drop must be bridged to secure the data in the RAM of the microcomputer 1. The energy storage 5 is designed so that its charge is sufficient to bridge this short time. As long as the normal voltage is applied to the microcomputer 1, the electrolytic capacitor becomes 5 charged, so that the full power of the electrolytic capacitor is available in an emergency stands.

Fig. 2 shows an embodiment of the device according to FIG a bridge circuit 6, alternating current is converted into direct current. A downstream Capacitor 7, preferably an electrolytic capacitor, serves to smooth the DC voltage and a capacitor 8, preferably a ceramic capacitor, for HF screening. The DC voltage is applied to an input 9 of a voltage regulator 10. He is Part of the voltage failure detector 4. A RESET output 11 of the voltage regulator 10 is connected via a line 12 to a transistor 13, which is in the in Fig. 2 is connected as shown. At an output 14 of the voltage regulator 10 there is a voltage of 5V, for example. Between the line 12 and a A resistor 16 is connected to the line 15 located at the output 14. An input is connected to it 17 of the voltage regulator 10, a timing element 18, preferably a capacitor, is connected. It supplies a delayed RESET signal when the voltage returns and ensures that no data is destroyed in the event of an undervoltage.

In order to filter out interfering components in the line 12, two filter capacitors are attached to it 19 and 20 connected, between which in the line 12 a screen resistor 21 lies. A diode 22 between the filter capacitor 20 and the transistor 13 is there the flow in line 12 to transistor 13 is free.

The modules 10, 18, 16, 19, 21, 20, 22 and 13 are part of the Power failure detector.

The line 12 is connected to the base of the transistor 13. The collector of the transistor 13 is connected to a Zener diode 24 via a line 23 connected, which is short-circuited during normal operation of the microcomputer 1. if the transistor 13 blocks, it switches the Zener diode 24 free, whereby the stabilization stage 3 is opened. the Zener diode 24 is part of the stabilization stage 3, which also contains a transistor 25, to the base of which the Zener diode 24 is connected is. The emitter of the transistor 25 is connected to the input 2 of the microcomputer 1.

The energy store 5 has a bridge circuit 26 for conversion of alternating current in direct current. Your is a capacitor 27, preferably an electrolytic capacitor, connected downstream, to the collector of the transistor 25 is connected. The zener diode 24 is a load resistor 28 and the transistor 13 a load resistor 29 connected downstream.

In normal operation, there is no voltage at input 2 of microcomputer 1 at. The transistor 25 is in the blocking position, so that the energy store 5 with the Capacitor 7 is separated from input 2. During normal operation, the capacitor 27 fully charged, so that in the event of a voltage drop, the full power of the energy storage device 5 is available. The transistor 13 is switched on, so that the Zener diode 24 is short-circuited.

In the event of a voltage drop, the voltage drops. This voltage drop is noticed by the power failure detector 4, which is designed so that it is in the event of a drop the voltage below a predetermined value at the output 11 a low signal as a switching signal gives away. The transistor 13 is blocked by this switching signal, whereby the Zener diode 24 is released. The transistor 25 of the stabilization stage 3 opens as a result, so that the required operating voltage can be taken from the energy store 5 can and at input 2 of the microcomputer 1 pending. These operations expire in a fraction of a second before the tension has completely collapsed is. This is achieved in that the voltage failure detector 4 does not only start at complete power failure, but the switching signal at output 11 delivers when the voltage falls below a specified value. That RAM of the microcomputer 1 is thus for the duration of the voltage drop with the necessary electricity.

When the voltage drop has been resolved and full voltage again is available, this operating voltage is only applied to input 2 with a delay of the microcomputer 1 delivered. This is achieved by the timer 18, which is on the bridge circuit 6 is connected.

When the voltage returns, the voltage regulator 10 initially delivers at the RESEE output 11 again a switching signal, so that the internal RAM of the microcomputer 1 briefly, that is, for a fraction of seconds, still from the energy store 5 with the necessary voltage is supplied.

After this time, the microcomputer checks whether the data is in RAM saved or lost. Is the voltage drop over? has occurred for a long time, the amount of charge of the capacitor 27 suffices does not stop at bridging the voltage dip. However, is the voltage dip been so short that the charge on the capacitor 27 is sufficient to bridge the voltage the data in the RAM has not been deleted. By the second switching signal after the voltage return, the microcomputer 1 can check whether the data are still present in RAM. Only then does the microcomputer 1 start again, wherein it is supplied with the necessary voltage by the applied operating voltage will. The delayed activation of the microcomputer 1 also ensures that only the microcomputer starts up again when the voltage is stable. As soon as the switching signal of the voltage failure detector 4 is absent, the transistor 13 turns on again, so that the Zener diode 24 is short-circuited and thus the transistor 25 is also blocked will.

The described delay in starting the microcomputer 1 after the voltage return is only a fraction of a second.

The possible time for voltage bridging depends on the Capacity of the capacitor 27. Since most of the voltage drops in the Usually takes less than 1 second, the capacitance of the capacitor 27 does not have to be too great be great.

The modules 13, 22, 20, 21, 19, 16 of the power failure detector 4 are necessary because the voltage regulator 10 supplies a low signal at output 11. Voltage regulators can also be used which have a high signal at output 11 deliver. In this case, building blocks 13, 22, 20, 21, 19, 16 are not required. The voltage regulator would then with its high signal directly the transistor 25 and the zener diode 24 switch. Instead of the bridge circuits 6 and 26, a other rectifiers, e.g. a half-wave rectifier, can be used.

Claims (13)

Claims 1. Device for backing up data in a RAM of a Microcomputer, which is connected to a voltage source, with an energy storage device, which is connected to an input of the microcomputer and a voltage drop the voltage source bridged, thereby g e k e n n z e i c h n e t that the energy storage (5) is connected to the microcomputer (1) via a stabilization stage (3), and that the stabilization stage (3) by an electronic voltage failure detector (4) is controlled, which is connected to the voltage source and in the event of a voltage drop emits a switching signal to the stabilization stage (3), which opens it and enables the voltage passage from the energy store (5) to the RAM. 2. Device according to claim 1, characterized in that the energy store (5) has at least one capacitor (27) which is connected to the stabilization stage (3) is connected to the input (2) of the microcomputer (1). 3. Device according to claim 1 or 2, characterized in that the stabilization stage (3) contains a transistor (25) from a Zener diode (24) is controllable. 4. Device according to claim 3, characterized in that the Zener diode (24) the switching signal of the voltage failure detector (4) can be supplied. 5. Device according to claim 3 or 4, characterized in that the transistor (25) of the stabilization stage (3) in normal operation of the microcomputer (1) is blocked. 6. Device according to one of claims 1 to 5, characterized in that that the voltage failure detector (4) contains a voltage regulator (10). 7. Einrichtuns according to claim 6, characterized in that the Voltage failure detector (4) a transistor connected downstream of the voltage regulator t10) (13), which is switched through during normal operation of the microcomputer (1) # t #: j5t - and whose collector is connected to the Zener diode (24). 8. Device according to claim 6 or 7, characterized in that the switching signal of the voltage regulator (10) the transistor (13) of the voltage failure detector (4) locks. 9. Device according to one of claims 6 to 8, characterized in that that the transistor (13) of the voltage failure detector 44) has a flow valve 22), preferably a diode is connected upstream. 10. Device according to one of claims 6 to 9, characterized in that that at an input (17) of the voltage regulator 10) a timing element (18), preferably a capacitor, is connected. 11. Device according to claim 10, characterized in that the Timing element (18) between the voltage regulator (10) - a rectifier (6) .vorzug R ise a bridge circuit, lies. 12. Device according to one of claims 1 to 11, characterized in that that the capacitor (27) of the energy store (5) with a further rectifier (26), preferably connected to a bridge circuit. 13. Device according to one of claims 10 to 12, characterized in that that the timer (18) sends a delayed RESET signal to the voltage return Input (2) of the microcomputer (1) supplies.