DE3322660A1 - Circuit arrangement for coupling two microcomputers - Google Patents

Abstract

Two microcomputers (M1, M2) are coupled by using clock pulses (T) which are transmitted from the first microcomputer (M1) to the second microcomputer (M2), and by using data (D1, D2) which are transmitted serially between the two microcomputers (M1, M2) after synchronisation with the clock pulses (T). The second microcomputer (M2) monitors the occurrence of the clock pulses (T) and, when the clock pulses (T) are missing, automatically carries out a predetermined programme sequence. The clock pulses (T) and the data (D1, D2) are transmitted between the two microcomputers (M1, M2) by using optoelectronic coupling elements (K1 to K3). The circuit arrangement can be provided in telephone terminals in which the first microcomputer (M1) is supplied by the power system via a power unit and the second microcomputer (M2), which can be constructed as dialling processor, is fed via the telephone line. In this case, it is still possible to dial a remote subscriber if the first microcomputer (M1) fails. <IMAGE>

Description

Schaltunqsanordnuna for coupling two microcomputers

The invention relates to a circuit arrangement for coupling of two microcomputers according to the preamble of claim 1.

It is already well known, telephone terminals with an additional Equipment, for example to provide actively illuminated displays or dialing aids. Such telephone terminals cannot normally be accessed from the telephone network take the required energy, but are usually additionally about Power supply units supplied from the normal power grid. A simple phone call is required, however be possible with these devices even if the power grid has failed. to for this purpose, a part fed by the telephone network is provided in the devices, who scans the numeric keys to establish a connection to the remote participant and pulses in the pulse dialing method and pulses in the multi-frequency dialing method can convert into frequencies.

In normal operation, the numeric keys are used by a microcomputer queried, which receives its supply voltage via a power supply unit from the power grid. This microcomputer sends dialing digits to a dialing device via an interface from that of the dialing device described above, powered by the telephone network is equivalent to.

From DE-OS 30 11 507 a circuit arrangement for mains-fed Telephone terminals known in the one Numeric keypad either Via optoelectronic coupling elements with a control device fed by the mains or can be connected to a dialing device fed by the telephone network. the Switching is done using a relay that responds when from one with the power supply connected to the mains supply the operating voltage.

If both in the mains-fed part and in the line-fed part Part of at least one microcomputer is provided, it is necessary to do this Connect microcomputers in a suitable manner, with as few lines as possible between the microcomputers should be available.

The present invention is therefore based on the object of a Specify circuit arrangement by means of the two microcomputers in a simple manner can be coupled with each other and by means of the at the same time also a simple Monitoring of at least one microcomputer is possible.

According to the invention, the object is achieved with the circuit arrangement. the type mentioned by the specified in the characterizing part of claim 1 Features solved.

The circuit arrangement according to the invention has the advantage that it requires extremely little effort and has a low power consumption. Furthermore, the circuit arrangement has a high level of operational reliability, since it is at the same time When the microcomputers are coupled, a microcomputer is monitored. the Clock pulses are used both for monitoring the microcomputer and for synchronization the transmission of data between the microcomputers at least in one direction.

If there is a galvanic separation between the two microcomputers is required, this is done in a simple manner using appropriate Coupling elements, in particular optoelectronic coupling elements.

To carry out mutual monitoring of the two microcomputers It is also possible to move from the second microcomputer to the first microcomputer To transmit clock pulses and to monitor their occurrence in the first microcomputer. In this case it is also possible to synchronize the transmission of Data from the second microcomputer to the first microcomputer these further clock pulses to use.

The circuit arrangement is then particularly advantageous used when the two microcomputers in a communication terminal, in particular a telephone device are arranged, wherein the first microcomputer via a network device is fed from the mains and the second microcomputer via the telephone network is fed. In this case, the second microcomputer is in particular a dialing processor provided, which then generates the dialing pulses when the first microcomputer does not more is operational. Due to the lack of clock pulses, the second Microcomputer determines the lack of operational readiness of the first microcomputer and asks the numeric keypad automatically, for example via a second set of contacts to then generate the dialing pulses for dialing a remote subscriber.

In normal operation, the repetition frequency of the dial pulses is such chosen that the dialing pulses can be generated in a simple manner. If the In the first microcomputer, the dialing pulses are provided by a second microcomputer internal timer generated.

The following is an embodiment of the circuit arrangement explained in more detail according to the invention with reference to a drawing.

The figure shows a circuit diagram of the circuit arrangement.

In the circuit arrangement shown in the figure, two Microcomputer 111 and M2 coupled to one another.

The two microcomputers M1 and M2 are, for example, in a telephone terminal arranged, wherein the microcomputer Ml is fed via a power supply unit from the power grid and the microcomputer M2 is fed from the telephone network. The functions of the telephone terminal are normally carried out by the microcomputer 111. However, if this is not operational, for example because the power grid has failed, the microcomputer M2 serves as a dialing processor for generating dialing pulses to dial a remote party. For this purpose, the microcomputer M2 scans a second one Contact set from a numeric keypad, while in normal operation the first contact set is scanned by the microcomputer 111.

Coupling elements are used for galvanic separation of the two microcomputers M1 and M2 K1 to K3 provided as a transmitter or preferably as an optoelectronic Coupling elements are formed.

The two microcomputers 111 and M2 are coupled by means of clock pulses T and data pulses Dl, which are transmitted from the microcomputer M1 to the microcomputer 112 and by data pulses D2 which are transmitted from the microcomputer M2 to the microcomputer M1 will. The clock pulses T are via the optoelectronic coupling element K1 as Clock pulses T1 and via two inverters I1 and 12 as clock pulses T2 and T3 to the microcomputer M2 fed to an interrupt input. This microcomputer M2 is located normally, i.e. with the microcomputer 111 ready for operation in an idle state, which is also under known as idle mode. In this idle state, the microcomputer consumes M2 particularly little energy. However, an internal timer is and will be in operation reset with each occurrence of a clock pulse T3 before reaching an end value achieved. If the clock pulses T3 fail due to a disturbance, for example because the microcomputer 111 is not ready for operation, the microcomputer leaves M2 the idle state and carries out a predetermined program sequence in which, for example the second contact set of the numeric keypad is queried and then the dialing pulses to create.

The microcomputer M1 transmits selection information and as data signals D1 Control information to the microcomputer M2.

A serial transmission method is used for this, in which each a predetermined number of bits, for example 5 bits, with a start and a stop bit. The data D1 is synchronized by the clock pulses T, which are sent via an inverter I3 to a first input of a NAND gate N1, at the second input of which the data pulses D1 are applied. the isochronous data signals DII at the output of the NAND element N1 are transmitted via an optoelectronic Coupling element K2 as data signals D12 and via an inverter I4 as data signals D13 fed to the microcomputer M2.

In the opposite direction, the microcomputer M2 transmits as data signals D2 Control information, such as end of digits, audible tone reception, charge pulses and similar information. A serial transmission with a start bit is also used here and a stop bit is used. The data signals D2 with the clock pulses T2 synchronized. For this purpose, the clock pulses T2 are a first The input of a NAND gate N2 is supplied, at whose second input the data signals D2 are present. The synchronized data signals D21 arrive via an optoelectronic Coupling element K3 as data signals D22 and via an inverter I5 as data signals D23 to the microcomputer M1.

The primary side of the optoelectronic coupling elements K1 and K2 and the secondary side of the optoelectronic coupling element K3 are via resistors R1 to R3 connected to the supply voltage U1 generated from the power grid, while the secondary side of the optoelectronic coupling elements K1 and K2 and the Primary side of the optoelectronic coupling element K3 via resistors R4 to R6 connected to a voltage U2 derived from the voltage in the telephone network are.

The polarity of the clock pulses T is chosen so that only during the Clock pulse time through the optoelectronic coupling element K1 current flows so that power consumption is reduced to a minimum. Still, it's in a simple way synchronization of the two microcomputers M1 and M2 is possible. When the clock pulses fail, the microcomputer M2 automatically detects that the microcomputer MI is not more works. In this case, telephoning is also possible when the microcomputer M1, for example because of a failure of the power grid, no longer is working.

It is also possible to send further clock pulses from the microcomputer M2 to the microcomputer MI in a similar way as the clock pulses T to be transmitted. In this case it is also possible to monitor the microcomputer M2 with the help of the microcomputer M7 and it would also be conceivable for the data signals D2 to be transmitted by these additional clock pulses instead of controlling the clock pulses T2.

10 claims 1 figure

Claims (10)

Circuit arrangement for coupling two microcomputers, in which clock pulses and data are transmitted between the microcomputers, d a d u r c h e k e n n n z e i c h -n e t that from the first microcomputer (dir) clock pulses (T) are transmitted to the second microcomputer (M2) that the second microcomputer (M2) monitors the occurrence of the clock pulses (T3) and if there are no clock pulses (T3) automatically carries out a predetermined program sequence and that the transmission of the data signals at least from the first to the second microcomputer (M1 or M2) serially and takes place under control of the clock pulses (T). 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the second microcomputer (M2) has a time stage which is reset with each received clock pulse (T3) before its timeout and which, if the clock pulse (T3) does not occur, the specified program sequence after the time has elapsed triggers. 3. Circuit arrangement according to claim 1 or claim 2, d a d u r c h e k e n n n n z e i c h n e t that in the connecting paths between the two Microcomputers (M1, M2) coupling elements (K1 to K3) are provided that support the microcomputers (M1, M2) galvanically separate from each other. 4. Circuit arrangement according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the coupling elements (K1 to K3) are optoelectronic coupling elements are provided. 5. Circuit arrangement according to one of claims 1 to 4, d a d u r c h g e k é n n n z e i c h n e t that from the second microcomputer (M2) to the first microcomputer (M1) further clock pulses are transmitted. 6. Circuit arrangement according to claim 5, d a d u r c h g e k e n n z e i c h n e t that the transmission of the data signals (D2) from the second microcomputer (M2) to the first microcomputer (M1) using the further clock pulses. 7. Circuit arrangement according to one of claims 1 to 6, d a d u r c h e k e n n n e i c h n e t that the microcomputers (M1, M2) in a communication terminal are arranged, wherein the first microcomputer (M1) via a power supply unit from the power grid and the second microcomputer is fed via the communication network. 8. Circuit arrangement according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the communication terminal is designed as a telephone terminal and the second microcomputer (M2) is fed via the telephone network. 9. Circuit arrangement according to claim 7 or claim 8, d a d u r c h e k e k e n n n n e i c h n e t that the second microcomputer (M2) as a dialing processor is designed and in the absence of the clock pulses (T3) as a predetermined program sequence queries provided in the communication terminal numeric keys to optionally a to select remote participants. 10. Circuit arrangement according to claim 9, d a d u r c h g e k e n n notifies that dialing pulses are generated for dialing the remote subscriber, which are derived from the clock pulses (T, T3) or if there are no clock pulses (T3) generated using the internal time stage in the second microcomputer (M2) will.