DE3502735C2 - Circuit arrangement for the dynamic real-time test of a synchronous digital circuit - Google Patents

Description

The invention relates to ac circuit arrangement for the dyna mix real-time test of a synchronous digital circuit according to the preamble of claim 1.

DE 25 38 651 A1 is a Ver drive and a device for testing digital circuits become known, a as a pulse train generator coupled clocked shift register is used, the Da input can be blocked by means of an AND gate. It is there is also a number plate generator for a parallel digita les signal of 16 bits wide specified, the input da tenbits can be combined with bits using exclusive NOR gates those that represent the previous state of the generator and cached in D flip-flops. That combined Tag is in a parallel or serial memory register cached.

The object of the present invention is a circuit to indicate arrangement of the type mentioned at the beginning with little additional funds allows both a self-test and a normal one Operation of the digital circuit.

The solution takes place with the characteristic features of the Main claim. There are advantageous further developments through the subclaims.

The advantage of the present circuit arrangement is in that the arrangement for operating the Di gitalschalt is switchable to a test mode, wherein a test loop is run independently. The extra wall for this is relatively small.  

There now follows the description of the invention with reference to the Figu ren.

Fig. 1 shows the principle of the test circuit for a self-test. Figs. 2 and 3 show the realization ei ner self-test switch by means of multiplexer switch. Fig. 4 shows the functional equivalence of closing OR gates and a four: one multiplexer.

Fig. 1 shows the input circuit of a digital circuit, in particular an integrated circuit IC, with a serial / parallel converter, which is designed as a shift register SR. Its m parallel outputs are connected to the m data inputs of the digital circuit IC. The information relationships linked by the digital circuit can be tapped at the n data outputs of the digital circuit IC. The shift register is fed via its serial input E ', which is connected via a changeover switch S to the input E of the digital circuit, with serial operating data.

A digital circuit operated in this way can advantageously be switched over to a self-test mode during the incoming goods inspection and during breaks in operation. For this purpose, the changeover switch S is flipped, whereby the data input E is disconnected. At the same time, the serial data input of the shift register SR is connected to a feedback loop by the changeover switch S. In this case, this feedback loop consists of two feedback couplings RK1, RK2, which are combined via an EXOR element and then inverted. The feedback branches RK1 and RK2 thus return from two selected flip-flop outputs of the shift register to the input of the shift register. The selection of the returns should take place in such a way that data sequences of maximum length are generated. In this way, with the feedback shift register, which has as many stages as there are data inputs on the digital circuit, the digital circuit with all possible combinations of input information is the most. With a shift register of length m, data sequences of maximum length 2 ^m -1 can be achieved, that is to say sequences of all possible words of length m with the exception of a single word. In order to be able to test this word as well, a shift register can be provided, which is expanded by one level in test mode.

The switchover from testing to normal operation or vice versa can be realized instead of the switch S according to FIG. 1 by a two: one multiplexer according to FIG. 2. Depending on the loading of its control input S, this multiplexer switches the feedback loop R via its input A0 or the data input E of the digital circuit via its other input A1 to its output Y, which is connected to the serial input of the shift register SR.

In the case of fast integrated circuits, for example using ECL technology, this combination of gate and multiplexer mux leads to runtime problems since the signal must pass through two gates between two effective clock edges. A time-uncritical implementation of the switchover and the feedback is possible with a four: one multiplexer, as shown in FIG. 3. This four: one multiplexer thus replaces the circuit and the switch S, that is to say both functions are fulfilled with this single module, as the two truth tables according to FIG. 4 show. The four: one multiplexer is switched as follows. The switching function U is located at its first set input S1, the feedback RK1 at its second set input S2. The two data inputs A0, A1 are assigned to the serial data input E of the digital circuit, while the other two data inputs A3, A2 are supplied with the signal RK2 or the negated signal of the second feedback loop. Thus, regardless of the loading of the set input S2 at S1 = L, the input data via the output Y of this four: one-multiple xers are read into the serial input E 'of the shift register SR. The feedback is open, so it is not effective. If S1 = H, either the second feedback branch or the inverted second feedback branch are switched to the input of the shift register. Data input E is open and ineffective.

The function of the negated EXOR gate in the feedback was therefore chosen after a system reset forbidden state of a zero permanent position in the slide to avoid register.

If the system is reset to binary 1, the binary 1 duration must be used position in the shift register can be avoided. This is accomplished by a non-inverting EXOR gate or by Ver exchange the two data inputs A2, A3 with RK2 and on the four: one multiplexer.

Claims (7)

1. Circuit arrangement for the dynamic real-time test of a synchronous digital circuit with m inputs and n outputs, with a pulse train generator which contains a feedback-controlled clocked shift register, the data input of which can be blocked, and which provides the pulse train for testing the digital circuit, characterized in that Shift register (SR) has at least m stages and is used to convert the serial operating input data into parallel operating input data for the digital circuit (IC), in that the stages are each assigned to a data input of the digital circuit and each have an output which is connected to the assigned data input , And that a mode switch (S) is provided, by which the normal operation of the digital circuit (IC) can be switched over to a test mode, the serial data input (E ') of the shift register (SR) from the serial data input (E) of the digital circuit is switched to the A Output of a feedback branch (R) starting from the shift register (SR) ( Fig. 1). 2. Circuit arrangement according to claim 1, characterized in  net that the feedback is chosen such that pulse follow maximum length arise. 3. Circuit arrangement according to claim 1 or 2, characterized ge indicates that two feedback branches (RK1, RK2) of two selectable register levels are provided. 4. Circuit arrangement according to claim 3, characterized in net that the two feedback branches via an exclusive OR gate (EXOR) are summarized. 5. Circuit arrangement according to one of the preceding Ansprü surface, characterized in that the switch is realized by a two: one multiplexer (Mux 2: 1) ( Fig. 2). 6. Circuit arrangement according to claim 3, characterized in that a four: one multiplexer (Mux 4: 1) is provided, of whose four inputs two inputs (A0, A1) are connected to the data input (E) of the circuit arrangement and two Inputs (A2, A3) are supplied with the signal of one feedback branch (RK2) and its inverted signal () and one control input (S2) of the signal of the other feedback branch (RK1) and its other control input (S1) of the signal ( U), which affects the switchover from normal operation to test mode, be acted on ( Fig. 3). 7. Use of the Circuit arrangement according to one of the preceding claims che in one inte five B / six B coders or decoders.