DD253311A1 - CIRCUIT ARRANGEMENT FOR THE TESTING OF MICRORECHNER CIRCUIT ARRANGEMENTS INCLUDING THE MICRORINE SELF - Google Patents

Abstract

The invention relates to a circuit arrangement for testing of microcomputers and microcomputer circuit arrangements of user systems whose development and testing is carried out with the aid of an emulator or development system and which find application in control engineering. According to the invention, a coupling point between the emulator and the user system for the signals addresses, data, system clock, command synchronization clock, interrupt recognition and addresses is additionally arranged. The emulator is connected in a known manner via an interface with a HOST computer whose program parts of its operating system are used directly in the Pruefablauf.

Description

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Field of application of the invention

The invention relates to a circuit arrangement for testing microcomputer circuit arrangements, including the microcomputer of user systems, whose development and testing is carried out with the aid of an emulator and which are used in control engineering.

Characteristic of the known technical solutions

For the development of software, computing systems are used which have large-scale software for various microcomputers in their operating systems, that is, the software can be developed, for example, for a U 8820 on a computing system with a U 880. The hardware development is supported by the software, in which specific programs that can be part of the end program are programmed in Eprom's for specific function tests of the hardware and plugged onto the circuit arrangement. This step-by-step approach is very tedious because of the additional development of the special programs and the necessary programming of the programs in Eprom's. The functional test by means of a special Eprom's is started by RESET on the microcomputer; the start address can not be varied; the program always runs in real time, i. Program execution in step mode is not possible. This inefficient, relatively separate development of software and hardware is eliminated by the use of a development system. Development systems, also called emulators, are building blocks with which functional units of original building blocks, such as microprocessors, can be partially or completely simulated by software.

Development systems are used, for example, to debug programs of microprocessors before the program is permanently and unalterably programmed into the program memory. Program execution is handled by the "USER microcomputer" located on the development system, AllPort lines - all lines of the microcomputer to which the user's circuitry can be connected - are provided by the development system In developing and testing the user's circuitry, the microcomputer on the user board itself is eliminated, that is, the user must note in his circuit design the condition that the microcomputer on the user board will not work while working with the development system This limitation also applies to the memory of the user microcomputer, and only the possibly configured additional memory connected to the PORT'S may remain active s are not detected directly and clearly on the user PCB. The development systems are characterized by an extensive command offer, which enables a very effective software and hardware development. For example, commands can be used to execute commands step-by-step or in real-time mode, register contents and status information can be queried and manipulated. The user program can be loaded in the RAM of the development system or processed from the Eprom. The processing can be started and stopped by command at any point. .

Such development systems are well known (DD 230660). The original microprocessor circuit is replaced by the development system itself. Thus, the serious disadvantage is visible that only the hardware from the user lines of the microprocessor, PORT'S, can be tested without the microprocessor itself. This disadvantage also applies to the known in-circuit emulators (DE 3408257), which is characterized by characterized extremely small design and can be used directly on site in the circuit configuration by the compatible structure (PIN, design) of emulator and original microprocessor.

Furthermore, circuit arrangements for the coupling of microcomputers of different internal structure (DD 214473) are known, which allow primarily the data exchange between the coupled microcomputers. The proposed coupling unit is suitable for the development and testing of user circuitry with microcomputers since the minimum requirement of reading the register contents of the subordinate microcomputer without using the user-specific PORT'S is satisfied. Extensive control signal conditioning is required for implementation, since the data and address bus control that connect the bus systems accordingly, are controlled by the parent microcomputer, without the direct use of the control signals of the slave microcomputer. As a result, the control and intervention of the superordinate microcomputer in the control signal play of the subordinate microcomputer during the program run is not possible. The machine time behavior of the subordinate microcomputer is not accessible to the higher-level microcomputer. The time behavior of the internal processes during command processing remains invisible.

Object of the invention

The aim of the invention is to reduce the hardware and software development costs as well as the hardware costs for the testing technology, to increase the effectiveness and to create conditions for automation.

Explanation of the essence of the invention

The invention has for its object to develop a circuit arrangement for testing microcomputer circuitry including the microcomputer itself, their development and testing is done with the help of an emulator. The condition that this function of the emulsifier, the previous functions are not limited, is to be guaranteed. The circuit is intended for the. Automation of the inspection process to be suitable.

Features of the invention

According to the invention the object is achieved in that an additional coupling point is created to lead to the emulator, the address lines, data lines of the user microcomputer and its control lines: addresses valid, system clock, command synchronization clock and interrupt recognition.

The software required for development, testing and testing is loaded in a RAM as a user memory, which is part of the emulator, with task-specific user programs and executed in any operating mode. In this specific case, the signal lines of the user microcomputer are routed to the emulsifier in the following manner:

- the data lines to the data multiplexer ^

The control line addresses valid As-the program counter and the read-breakpoint register and the I-code register;

The address lines on the address multiplexer;

- the control line - interrupt recognition IACK - to the PORT input of the monitor microcomputer;

- the control line - command synchronization clock SYNC - to the Go-ZTrace ZStop logic, the program counter - and the read-breakpoint register, the user memory, the I-code register and the decoder control logic and

The signal line - system clock SCLK - to the I-code register and the data multiplexer.

In order to allow a separate power supply of the development system and the user circuit arrangement, the masses of the supply voltage of the user microcomputer and a monitor microcomputer are to be connected. By connecting the user circuitry to the coupling point described above, the object of the invention is achieved.

embodiment

The invention will be explained in more detail below using an exemplary embodiment.

For the user microcomputer 15 to be included in the test procedure, the operating program is stored in an EPROM 14 on the user. An additionally created coupling point contains the signals for the user microcomputer 15: addresses A0 to A10, data D0 to D7, addresses valid AS, system clock SCLK, command synchronization clock SYNC, interrupt acknowledge IACK and ground.

As a result of the realized coupling, the soldered microcomputer 15 and the user circuit arrangement 16 connected via the PORT interface 17 can be controlled by the monitor microcomputer 5 of the development system. This makes it possible to check all the internal functional units of the microcomputer 15 being soldered in, for example the PORT driver, the arithmetic logic processing unit, the program counter, the internal control logic in the instruction execution, the control registers, the internal RAM, the interrupt control, the internal Clock generation, command control, internal reset logic, internal timer / counter and serial input / output functional units, and its clock generation 13 during program execution or through development system commands. The user program can be stored in the user memory, the RAM 10 of the development system. This results in tightly coupled hardware and software development. Program changes can be made in RAM the same, and the effects of program execution on user circuitry 16 can be determined. By using the user memory 10, in which programs of data carriers can be loaded from the higher-level HOST computer system 1 very quickly and without problems, the user circuitry 16 can be tested quickly by an unlimited number of test programs. The test programs no longer need to be loaded into EPROMs and plugged into the user circuit. This increases the reliability of the test procedure. The test programs are slightly modified parts of the program

Operation program; they no longer need to be written under the condition of using minimal space. The test program can use the possibilities of the higher-level HOST computer system 1. For example, the test program can evaluate states and bit patterns of the registers of the user microcomputer 15 itself and forward the result via the serial interface 2 to the HOST computer system 1, which carries out the conversion, such as an output generated on the monitor: "Function 1 checked "" Function module 2 defective "

and so on. Thus arises independently on the HOST computer system 1, a test protocol that can be printed and the user circuitry 16 accompanied the repair site, which has the same structure.

This described multi-computer configuration with the inventive coupling of the emulator with the user is particularly suitable for the automatic testing of printed circuit boards with microcomputer circuitry whose operating program is stored in external memories, since the register contents of the user microcomputer 15 can be read and evaluated by the emulator. For example, test programs can be created by which the reloading of test programs from the HOST computer system 1 is initialized and started as a function of the determined error, by analyzing the register contents of the microcomputer 16, the monitor microcomputer 5 of the EMU.

The circuit arrangement of the known emulator, consisting of: monitor microcomputer 5, Monitor 3, decoder control logic 6, clock generation of the monitor microcomputer 4, serial interface 2 between the emulator and HOST computing system, Adfeßmultiplexer 7, go / trace / stop logic 8, program counter / Read ZBreakpointregister 9, user memory 10,1-code register 11 and data multiplexer 12 is functionally extended when using the coupling according to the invention. As a result, all commands of the emulator can be used without restriction even during the test process. This advantage is significant in testing and repair, that is, in fault location with defective user circuitry. This provides a unit from software and hardware development to the repair of circuit arrangements without additional hardware complexity.

The extensive functions of the development system are retained by the inventive coupling of the emulator with the user circuitry and characterize this configuration as a universal comfortable development and testing device for microcomputer circuitry.

Claims (2)

A microcomputer circuit arrangement testing apparatus including a microcomputer connected thereto through a PORT interface and developed and tested by means of an emulator linked to a HOST processor through another interface, characterized in that between the Emulator and the user microcomputer (15) a coupling point for the signals addresses valid AS, interrupt recognition IACK, command synchronization clock SYNC, system clock SCLK and addresses (AO ... A10) and data (DO ... D7) is created, and that a RAM as User memory (10) is arranged for specific user programs on the emulator. 2. A circuit arrangement according to claim 1, characterized in that the signal lines of the user microcomputer (15) are guided on the emulator, that - the control line - addresses valid AS - with the Programmerzähler and read-breakpoint register (9) and the I-code register (11); - The control line - Interruptanerkennung IACK with the PORT input of the monitor computer (5); The control line - command synchronization clock SYNC - with the go / trace / stop logic (8), the program counter and read breakpoint register (9), the user memory (10), the I-Coderregister (11) and the decoder control logic (6 ); The signal line - system clock SCLK - with the I-code register (11) and the data multiplexer (12); - The data line (DO ... D7) with the data multiplexer (12) and the EPROM (14) of the user and - The address lines (AO ... A10) with the address multiplexer (7) and the EPROM (14) of the user are connected.