HU187029B - Programmable measuring system of controlled run and emulator for using in measuring system - Google Patents

Abstract

The invention relates in particular to an integrated circuit, in particular for the continuous monitoring of correct operation in LSI and VLSI integrated circuit measuring machines, and for simultaneous signaling of hardware and software failures, and for defining the fault location The signal system according to the invention can be connected to the computer by means of 10 bi-directional bus systems (1). (20) comprises a generator and programmed units (30), and an OUT interface unit (40), which DUT interface unit (4) is connected to the programmed units (3) by way of lines (31) defining the environmental conditions and the signal generator (2). ) and the DUT interface unit (4) are interconnected by way of signal lines (21) and first response pattern lines (41). The essence of the measuring device is that the fault collecting and evaluating logic (60) as well as the masking and comparative logl (5), and the bidirectional bus system (1 bow coupled emulator (70), the signal generator is one input of the emulator (70)). (20) is connected via a control line (22) and a synchronization line (23), the first input group of the masking and comparative logic (5) is connected to the signal line (21) and the sample lines of the second input group (70) to the emulator (70) , the masking and comparative logic (5) is connected to the input of the fault collecting and evaluating logic (6) via the fault line (51), and the fault collecting and evaluating logic (60) to the second interrupt line (62) to the signal generator. (20) and a third error interrupt line (63) connected to the emulator (70) and connected to the computer (10) by a first error interrupt line (61) ) -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a controlled run programmable milking system and an emulator for use in the system, which is preferably used to continuously monitor the correct operation of integrated circuits, in particular LSI and VLSI integrated current measuring machines, to simultaneously detect and locate malfunctioning hardware and software. The measuring system of the present invention comprises a bidirectional bus system-connected signal pattern generator and programmed units, a DUT interface unit coupled to the programmed units via lines defining environmental conditions, and the signal pattern generator and the DUT interface unit interconnecting signal pattern lines and a first response pattern. are connected by lines.

Known self-testing solutions test the functional operation of the measuring equipment either outside or inside the operating hours. In the first case, the time and effect of a fault can only be limited to a limited extent between two checks, so revealing the cause of a fault after a fault discovery requires considerable machine time lost in normal use and the acceptability of measurements during the fault period. In the second case, the most common solution is to use error detection and error correction codes. This makes the construction and programs of measuring equipment very complicated and expensive. In less widespread solutions, redundant units in the measuring equipment parts to be checked are juvenile. build circuits which, in the event of a failure, take over the function of the controlled measuring part or provide an error message. Such solutions are more expensive than the former.

Increasing the reliability of programmable measuring systems used for the measurement of complex integrated circuits, reducing the unit-specific operating time as a cost. For LSI, VLSI integrated circuits, including at least 3 times measurement (verification) during manufacturing, it can achieve 20-25% of the circuit cost, necessitating the design of a measuring system that can be controlled by a programmable measuring system at runtime and software or hardware in the event of a fault, the cause or failure of the fault. allows you to pinpoint your location with great accuracy.

Λ The invention is based on the recognition that programmable measuring systems containing a high operating speed signal sample generator must be continuously monitored at the same time as running. The measuring equipment part designed for the control shall perform the in-process control by running the signal sample generator and the functions of its associated units from clock to clock or from clock to clock. it has to emulate from instruction to instruction, thus providing the possibility of repeating a faulty cycle or interrupting the program when an error is detected.

The present invention provides a controlled run programmable measuring system comprising a bidirectional bus system-connected signal pattern generator and programmed units, and a DUT interface unit, which is a DUT interface unit that defines lines for environmental conditions for the programmed units. The signal pattern generator and the DUT interface unit are interconnected via signal pattern lines and first response pattern lines. The measuring system consists of error collecting and evaluating logic, masking and comparing logic, and a two-way bus system emulator connected to each input of the emulator via the signal generator control line and synchronization line, the first input group of the masking and comparing logic connected to lines and connected to the emulator by a group of second inputs, connected to the emulator by control lines, masking and comparing logic connected via a fault line to the input of error logging and evaluating logic, error logging and evaluating logic by a second error interrupt line to the signal generator and a third interrupt is connected via a line to the emulator and the first error to connect to the computer is provided with an interrupt line.

During operation of the weighing system according to the invention, the system control computer loads the programmed units, the signal generator and the emulator. When running the program, the emulator, by synchronizing and controlling the signal generator, produces signal patterns identical to the signal pattern generator, compares the signal patterns and control patterns with masking and autoconfiguration logic, and generates an error signal to operate the error logger generating error logic. and interrupts the program of the emulator and the computer by either repeating the malfunctioning cycle or by saving the information needed to determine the error to stop the measuring system.

In a preferred embodiment of the measuring system, the DUT interface unit is connected directly to the emulator via second response pattern lines, which also provides a means of checking the comparative function of the signal pattern generator.

It is a further object of the present invention to provide an emulator for such measuring systems. The emulator of the present invention has a synchronous control memory and a control command line connected sample generator having a synchronous control memory connectable to a bidirectional bus system and having a response sample input, a control input and a third error interrupt line receiving input, wherein the sample generator has a synchronization sample having a design.

BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENT The present invention will now be described with reference to the preferred embodiment. pushed drawings where it is

Fig. 1 is a block diagram of the metering system of the present invention with a connection between its main units and a

Figure 2 shows a detail of the measuring system of Figure 1 with a block diagram of the emulator and its associated units.

As shown in Figure 1, the measuring system has a system control computer 10 which is connected via a bidirectional bus system 11 to environmental conditions e.g. DC current and voltage levels etc. with 30 programmed units, 20 signal generators for generating test signals, and 70 emulators.

The measuring system further includes a DUT interface unit 40 including drive and comparator circuits that are directly coupled to the circuit to be measured, which is coupled to the programmed units 30 via the environment condition determining lines 31 and the signal pattern generator 20 via signal pattern lines 21 and first response lines 41.

The measuring system has a masking and comparing logic 50 having a first input group connected to the signal pattern lines 21 and a second input group of control pattern 71 lines connected to the emulator 70.

The output of the masking and comparing logic 50 is connected via line 51 to the input of error acquisition and evaluation logic 60, the first error interrupt line 61 to computer 10, the second error interrupt line 62 to the signal generator 20 and the third error interrupt It is connected via line 63 to emulator 70.

The signal pattern generator 20 is coupled to the emulator 70 via a control line 22 and a synchronization line 23, and the second response pattern 40 of the DUT interface unit 40 is directly coupled to the emulator 70.

The function of the system control computer 10 is twofold: it charges the measuring system units through the bidirectional bus system 11 and coordinates their operation. The structure of the signal sample generator 20 is designed according to the measurement technique. Its high operating speed ensures the production of new output and reference signal pattern sequences from cycle to cycle, and the continuity of the signal pattern sequences. The programmed units 30 provide reference levels of the druver and comparator circuits of the DUT interface unit 40 that drives the circuit to be measured.

The emulator 70 is also charged to the bus system 11 from the computer 10. Direct control signals are received on the control line 22 and synchronization signals on the synchronization line 23 from the signal pattern generator 20.

During testing of a circuit according to the program executed, the signal sample generator 20 generates signal samples which are transmitted by the signal sample line 21 to the DUT interface unit 40. The DUT interface unit 40 also receives the ambient (measurement) conditions on the lines 31, such as power supplies, reference levels, and timing signals from the programmed units 30. As a result of the measurement, the response samples received from the measured circuit are transmitted by the DUT interface unit 40 to the signal pattern generator 20, which compares it with the reference signal sample and evaluates the measured circuit, thereby allowing the measurement program to be transmitted when the response samples and reference signal samples match.

The measuring system is controlled by the masking and comparing logic 50 generated by the signal pattern generator 20 and appearing on the signal pattern line 21 and generated on the control pattern line 71 generated by the emulator 70 controlled and sub-synchronized to the signal pattern generator 20. compares with signals per cycle. In the event of a deviation, it generates an error signal which is transmitted by the error signal on line 51 to the error logic 60. The logging and evaluation logic 60 evaluates the error and, depending on the program, either stores the data needed to determine the location of the error or interrupts the program, thereby stopping the signal generator 20 via its signal 62 and stopping the signal at line 63. and emits an interrupt signal to the computer 10 on the line.

At the same time, the emulator 70 receives the response samples of the measured circuit directly through the second response sample line 42 and compares it with the control signal samples it produces. The result of the comparison, which may indicate a malfunction of the signal sample generator 20 in the event of a deviation, is stored and, at the end of the measurement, read by the computer 10 via the bus system 11.

Figure 2 shows a block diagram of the emulator 70 and units directly connected to the emulator 70, including a block diagram of the signal sample generator 20.

The emulator 70 has a synchronous control memory 74 and a sub-control command generator 72 connected by lines 73. The signal generator 20 typically includes a control memory 24 and a control unit 25, and a data generator 26, an address generator 27 and a direct control unit 28 connected to the control unit 25 via command lines 29.

The synchronous control memory 74 of the emulator 70 is coupled to the bus system 11 and has a second input sample receiving line 42, a control line 22 and a third interrupt line 63. The pattern generator 72 has a synchronization input receiving a synchronization line 23 and a control sample line 71 having a related sample supplying output.

The control memory 24 and the control unit 25 of the signal pattern generator 20 are connected to the bus system 11. The control unit 25 is provided with an input receiving a first sample line 41 and a second error interrupt line, and a controller or control line connected to the synchronizing line 23 and the control line 22. output of a synchronizing signal.

The data generator 26 output of the signal pattern generator 20 is connected to the data sample line 21A, the address generator 27 output is the address sample line 21B and the direct control unit output is a direct drive line 2IC formed by lines 21A, 21B and 21C.

The signal pattern 21 shown in FIG.

During operation, control samples corresponding to data samples, address samples and direct control command signals generated by each of the signal pattern generator 20 are generated by the pattern generator 72 synchronized by the signal pattern generator 20 and operated by the synchronous control memory 74 controlled by the signal pattern generator 20.

The response samples from the measured circuitry are evaluated by the control unit 25 in the signal sample generator 20 and the synchronous control memory 74 in the emulator 70. The error acquisition and evaluation logic 60 operated by the masking and comparing logic 50 disables the synchronous control memory 74 in the emulator 70 and the control unit 25 in the signal pattern generator 20.

The main advantage of the present invention is that it provides an indication at the same time as the known self-test solution, at the time the error occurs, and also provides the information needed to limit it.

Claims (3)

1. Controlled run! a programmable measuring system comprising a signal generator (20) and programmable units (3) which can be connected to a computer (10) with a bidirectional bisystem (11), and a DUT interface unit (40), which DUT interface unit (40) for the programmed units (30) connected via condition defining lines (31), and the signal pattern generator (20) and the DUT interface unit (40) interconnected by signal pattern lines (21) and first response pattern lines (41), characterized in that its error collecting and evaluating logic ( 60) and a logic and comparative logic (50) further comprising an emulator (70) coupled to the bidirectional bus system 01), via a control line (22) and a synchronization line (23) for each input of the emulator (70). connected, the first input group of the masking and comparing logic (50) is connected to the signal pattern lines (21) and the second input group with the emulator (70) being connected via control lines (71), the masking and comparing logic (5) being connected via an error signal line to the input of the error acquisition and evaluation logic (60), and a second error interrupt (60). line 62 is connected to the signal generator 20 and a third interrupt line 63 to the emulator 70 and is provided with a first interrupt line 61 connected to a computer 1. An embodiment of a measuring system according to claim 1, characterized in that the DUT inter10 face unit (40) is connected directly to the emulator (70) via a second response pattern line (42). An emulator, particularly for a measuring system according to claim 1 or 2, characterized in that the synchronous control memory (74) and a sample generator (72) connected thereto by a control command line (73). 1® having a synchronous control memory (74) design for connection to a bidirectional bus system and having a response sample input, control inputs, and a third error interrupt line receiving input, wherein the pattern generator (72) has a sync2Q climbing input and control pattern output.