JP4495332B2 - Driver control signal generation circuit / IC test equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an IC test apparatus for testing, for example, a semiconductor integrated circuit element (hereinafter referred to as an IC). In particular, the present invention relates to testing a device under test at high speed by operating a driver for applying a test pattern signal to the device under test. It is the purpose.
[0002]
[Prior art]
FIG. 8 shows a schematic configuration of the IC test apparatus. In the figure, TES indicates the entire IC test apparatus. The IC test apparatus TES includes a main controller 11, a pattern generator 12, a timing generator 13, a waveform formatter 14, a logic comparator 15, a driver 16, a comparison reference voltage source 22, a device power supply 23, and a driver control signal. The generation circuit 24 is configured.
The main controller 11 is generally constituted by a computer system, and mainly controls the pattern generator 12 and the timing generator 13 according to a test program created by the user. The pattern generator 12 controls the test pattern data. The test pattern data is converted into a test pattern signal having an actual waveform by the waveform formatter 14, and the test pattern signal is set by the logic amplitude reference voltage source 21. It is applied and stored in the device under test 19 through a driver 16 that amplifies the waveform having an amplitude value.
[0003]
The response signal read from the device under test 19 is compared with the reference voltage supplied from the comparison reference voltage source 22 by the analog comparator 17 and whether or not it has a predetermined logic level (H logic voltage, L logic voltage). The signal that has been determined to have a predetermined logic level is compared with the expected value output from the pattern generator 12 by the logic comparator 15, and if there is a mismatch with the expected value, the signal is read out. It is determined that there is a mismatch in the memory cell at the address, and a defective address is stored in the defect analysis memory 18 every time a defect occurs, and it is determined whether the defective cell can be repaired, for example, at the end of the test.
[0004]
When the terminal of the device under test 19 is an input / output pin (I / 0 pin), the output terminal of the driver 16 and the input terminal of the analog comparator 17 are connected in common, and the driver 16 is connected to the device under test 19. After supplying the test pattern signal, at the timing when the device under test 19 outputs a response signal, the driver 16 controls the output impedance to a high impedance, thereby reducing the load on the device under test 19 and testing the device under test. The deterioration of the waveform quality of the response signal of the device 19 is prevented, and the response signal having the highest waveform quality is input to the analog comparator 17 as much as possible.
[0005]
For this purpose, a driver control signal generation circuit 24 is conventionally provided. A waveform generation control signal is input from the waveform formatter 14 to the driver control signal generation circuit 24, and a clock which is a timing reference from the timing generator 13 is provided. And a driver control signal is generated based on the waveform generation control signal and the timing signal.
FIG. 9 shows a configuration of a conventional driver control signal generation circuit 24. In this example, the driver control signal generation circuit 24 is constituted by two AND gates G1 and G2 and one SR flip-flop SR-FF. Timing clocks LCK and TCK defining the rising timing and falling timing of the driver control signal DRE are input from the timing generators 13A and 13B to one input terminal of each of the two AND gates G1 and G2.
[0006]
Waveform generation control signals DRE-L and DRE-T are input from the waveform formatter 14 to the other input terminals of the two AND gates G1 and G2. When the waveform generation control signals DRE-L and DRE-T are “1” logic, the AND gate G1 or G2 is controlled to be in an open state, and the timing clock LCK or TCK is applied in this open state. The driver control signal DRE is generated by applying a set pulse or a reset pulse to the set input terminal S or the reset input terminal R of the SR flip-flop SR-FF.
[0007]
The waveform formatter 14 has a waveform memory 14A for storing waveform generation control data, a multiplexer MUX for selecting pattern data DRE1 and DRE2 given from the pattern generator 12, and a waveform mode. And a register RG to be set.
That is, the waveform mode read from the waveform memory 14A is switched in accordance with the setting of the mode set in the register RG, and the driver control signal DRE is generated as an RZ waveform (Rerun to Zero) or an NRZ waveform ( Non-Rerun to Zero) can be selected.
[0008]
The multiplexer MUX selects one of the pattern data DRE1 and DRE2 supplied from the pattern generator 12 in accordance with the select signal SEL set in the register RG, and selects either of the pattern data DRE1 or DRE2. Is applied to the address input terminal of the waveform memory 14A, and the waveform generation control signals DRE-L and DRE-T are read according to the logical values of the pattern data DRE1 or DRE2.
FIG. 10 shows an example of the waveform generation control signals DRE-L and DRE-T read by either the pattern data DRE1 or DRE2. Either one of the pattern data DRE1 and DRE2 is selected by the select signal SEL and applied to the waveform memory 14A. That is, when the select signal SEL is “0” logic, the pattern data DRE1 is selected and applied to the waveform memory 14A. When the select signal SEL is “1” logic, the pattern data DRE2 is selected and applied to the waveform memory 14A.
[0009]
In the RZ waveform mode, when the pattern data DRE1 changes to 0, 1, 0, 1, for example, the waveform generation control signals DRE-L and DRE-T are 0, as shown in FIG. It changes to 1, 0, 1 and DRE-T also changes to 0, 1, 0, 1. When these waveform generation control signals DRE-T and DRE-T are applied to the driver control signal generation circuit 24, the RZ waveform shown in FIG. 11H is applied to the mode switching terminal of the driver 16.
That is, FIG. 11A shows the pattern data DRE1. 11B and 11C show timing clocks LCK and TCK output from the timing generators 13A and 13B. The generation timings t1 and t2 of the timing clocks LCK and TCK are set by the timing generators 13A and 13B, and specify at what timing the driver control signal DRE is raised or lowered within the time range of the test cycle T. To do.
[0010]
In the RZ waveform mode, when the pattern data DRE1 is “0” logic, the waveform generation control signals DRE-L and DRE-T both output “0” logic, and the pattern data DRE1 is When the logic is “1”, the waveform generation control signals DRE-L and DRE-T are both “1” logic (see FIGS. 11D and 11E), and the pattern data DRE1 is “1” logic test cycle. Only when the timing clocks LCK and TCK are applied to the set input terminal S and the reset input terminal R of the SR flip-flop SR-FF through the AND gates G1 and G2, the SR flip-flop SR-FF is shown in FIG. 11H. A driver control signal DRE having an RZ waveform is generated, and this driver control signal DRE is applied to the mode switching terminal of the driver 16. Therefore, in the RZ waveform mode using the pattern data DRE1, the driver 16 repeats the high impedance mode and the output mode every other test cycle.
[0011]
FIG. 12 shows a case where DRE2 is used as the pattern data. When the pattern data DRE2 is used, the driver control signal DRE repeats the high impedance mode and the output mode every two test cycles as shown in FIG. 12H.
FIG. 13 shows the case of the NRZ waveform mode. In the NRZ waveform mode, as shown in FIG. 10, when the pattern data DRE1 is “0”, the waveform generation control signals DRE-L and DRE-T are “0” logic, DRE− T becomes “1” logic, and when the pattern data DRE1 is “1”, DRE-L becomes “1” logic and DRE-T becomes “0” logic (see FIGS. 13D and E). When the waveform generation control signal DRE-L is “1” logic, the timing clock LCK is applied to the set input terminal S of the SR flip-flop SR-FF, and when the waveform generation control signal DRE-T is “1” logic, SR The timing clock TCK is applied to the reset input terminal R of the flip SR-FF.
[0012]
Therefore, the SR flip-flop SR-FF generates the driver control signal DRE having the NRZ waveform mode (which does not return to 0 in the period of one test cycle) shown in FIG. 13H.
FIG. 14 shows the case of the NRZ waveform mode when the pattern data DRE2 is used. In this case, the driver 16 is maintained in the high impedance mode and the output mode for two test cycles, and this is repeated.
The driver control signal generation circuit 24 described above shows an example of a driver control circuit having a simple configuration. Since the driver control circuit 24 having a simple configuration has a simple configuration, some functions are omitted.
[0013]
That is, as shown in FIGS. 11 to 14, the driver control signal generation circuit 24 shown in FIG. 9 can generate only the driver control signals of the RZ waveform mode and the NRZ waveform mode.
In order to test a recent high-speed memory, for example, a (Double Data Rate system) memory, it is necessary to realize switching of IO within a period of one test cycle. For this purpose, a DNRZ waveform mode waveform must be generated as a driver control signal.
[0014]
Conventionally, there has been a driver control signal generation circuit capable of generating a driver control signal in the DNRZ waveform mode. An example is shown in FIG. In order to generate the driver control signal in the DNRZ waveform mode, if the number of timing generators shown in FIG. 9 is N, the number of timing generators in FIG. 15 is 2N of 13A, 13B, 13C, and 13D. Timing clocks LCK1 and LCK3 and TCK1 and TCK3 are supplied to one input terminal of each of 2N AND gates G1 to G4.
Waveform generation control signals DRE-L1, DRE-L3, DRE-T1, and DRE-T3 are supplied from the waveform formatter 14 to the other input terminals of the AND gates G1 to G4, respectively.
[0015]
An example of the waveform generation control signals DRE-L1, DRE-L3, DRE-T1, and DRE-T3 output from the waveform formatter 14 is shown in FIG. As shown in FIG. 16, in the RZ waveform mode and the NRZ waveform mode, the waveform generation control signals DRE-L3 and DRE-T1 given to the AND gates G2 and G3 are all set to "0" logic. -G2 and G3 are not used at all. That is, an operation equivalent to that of the driver control signal generation circuit 24 having a simple configuration shown in FIG. 9 is performed.
On the other hand, in the DNRZ waveform mode used for the high-speed test, the waveform generation control signals DRE-L3 and DRE-T1 are both in the state that the pattern data DRE1 and DRE2 are in the “0” logic state, and DRE1 is “ When DRE2 is “1” and DRE2 is “1”, DRE-L3 becomes “1” logic. The waveform generation control signal DRE-T1 outputs “1” logic when DRE1 is “0” and DRE2 is “1”, and becomes “1” when both DRE1 and DRE2 are “1” logic.
[0016]
In this way, when the waveform generation control signals DRE-L3 and DRE-T1 are in the logic “1” state, the timing clocks LCK2 and TCK1 are added to the timing clocks LCK1 and TCK3 output from the AND gates G1 and G4. Since it is output to the SR flip-flop SR-FF, a driver control signal in the DNRZ waveform mode can be generated.
17 to 18 show the operation of the high-function driver control signal generation circuit 24. FIG. FIG. 17 shows the operating state of the RZ waveform mode. The example shown in FIGS. 17 to 19 shows a case where the pattern data DRE1 and DRE2 are set to 1, 0, 1, 0, 1 and 0, 1, 0, 1, 0,.
[0017]
FIG. 18 shows a state in which the driver control signal DRE is generated in the NRZ waveform mode, and FIG. 19 shows the DNRZ waveform mode.
In the DNRZ waveform mode, the four AND gates G1 to G4 open and close as described above, and the AND outputs of the two AND gates G1 and G3 and the AND outputs of G2 and G4 are respectively OR gate OR1. And OR2, and the SR flip-flop SR-FF is supplied with timing clocks LCK1, LCK3, TCK1, and TCK3, respectively, so that the SR flip-flop is compared with the case where the AND gates G2 and G3 do not exist. The number N of timing clocks applied to the SR-FF can be doubled. In this respect, the driver control signal DRE can be switched at high speed.
[0018]
[Problems to be solved by the invention]
As described above, the high-function type driver control signal generation circuit 24 that enables high-speed testing requires four timing generators. To explain more detailed parts, the pattern data DRE1 and DRE2 are used. It is prepared for each pin (same as for each driver). For this reason, there exists a fault which will become an expensive test apparatus with a large scale of a test apparatus.
Therefore, it is conventionally used as a test apparatus for developing a semiconductor memory that requires high functionality regardless of cost.
[0019]
An object of the present invention is to propose a simple high-performance driver control signal generation circuit capable of realizing an operation equivalent to that of a high-performance driver control signal generation circuit without incurring costs.
[0020]
[Means for Solving the Problems]
According to the first aspect of the present invention, N timing clocks output from the N timing generators and having a phase difference from each other are applied to one input terminal of the N gates. Are controlled by N waveform generation control signals output from the waveform formatter, and the SR flip-flop is set and reset by a timing clock selectively taken out to the gate output side to set various waveform models. A driver control signal generation circuit for generating a driver control signal for a driver and switching the driver between a high impedance mode and an output mode according to the driver control signal;
By dividing the output of the N timing generators into two, 2 · N timing clocks are obtained, and this 2 · N timing clock is applied to one input terminal of the 2 · N gates. A driver control signal generation circuit is proposed in which the 2 · N gates are controlled to open and close by 2 · N system waveform generation control signals output from the waveform formatter.
[0021]
According to a second aspect of the present invention, a pair of pulsing circuits that generate a pulse at each timing of rising and falling of a clock that defines the operation sequence of the IC test apparatus;
An SR flip-flop for supplying a logical sum of pulse trains obtained from the pair of pulsing circuits to a set input terminal and a reset input terminal to generate a driver control signal for controlling the driver in an output mode and a high impedance mode; ,
A driver control signal generation circuit configured by the following is proposed.
[0022]
According to a third aspect of the present invention, a test pattern signal is applied to the device under test through a driver, the response signal of the device under test is compared with an expected value, and the quality of the device under test is determined according to the comparison result. In IC test equipment,
An IC test apparatus configured to apply a driver control signal from any one of the driver control signal generation circuits according to claim 1 to a control input terminal of the driver is proposed.
[0023]
[Action]
According to the driver control signal generation circuit proposed in claim 1 of the present invention, a multi-system timing clock is generated by a small number of timing generators, and the multi-system timing clock is supplied to 2 · N gates. Therefore, it is selectively extracted, and the SR flip-flop is set and reset by this extracted timing clock to generate driver control signals of various waveform modes, so it is equivalent to a high-functional driver control signal generation circuit at low cost A driver control signal generation circuit having the above functions can be configured.
[0024]
Further, according to the driver control signal generation circuit proposed in claim 2 of the present invention, there is a disadvantage that only a single waveform mode can be generated, but the driver control capable of performing a high-speed test very simply is possible. A signal generation circuit can be obtained. Therefore, it is possible to provide an advantage that a low-cost IC test apparatus can be provided by applying to a case where an IC under test is tested only in a single operation mode.
Furthermore, according to the IC test apparatus proposed in claim 3 of the present invention, it is possible to provide an inexpensive IC test apparatus as a whole even if the driver control signal generation circuit of claim 1 or 2 is used. Benefits that can be obtained.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an embodiment of a driver control signal generation circuit proposed in claim 1 of the present invention. Portions corresponding to those in FIGS. 9 and 15 are denoted by the same reference numerals.
The configuration which is a feature of the present invention generates 2 · N system timing clocks by bifurcating the outputs of N timing generators, and the 2 · N system timing clocks are read from the waveform formatter 14. The gate is selectively extracted by a gate that is controlled to open and close by 2 · N system waveform generation control signals, and the selectively extracted timing clock is applied to the set input terminal S and the reset input terminal R of the SR flip-flop SR-FF. It is the point made into the structure to do.
[0026]
That is, this embodiment shows an embodiment in which the output of two timing clocks 13A and 13B is branched into two to generate 2 × 2 = 4 timing clocks. The timing clock LCK output from the timing generator 13A is branched into two and input to one input terminal of each of the gates G1 and G2. The timing clock TCK output from the timing generator 13B is also branched into two and input to one of the input terminals of the gates G3 and G4.
A waveform generation control signal DRE-L1 read from the waveform memory 14A constituting the waveform formatter 14 is applied to the other input terminal of the gate G1. A waveform generation control signal DRE-L3 read from the waveform memory 14A is applied to the other input terminal of the gate G2. A waveform generation control signal DRE-T1 read from the waveform memory 14A is applied to the other input terminal of the gate G3. A waveform generation control signal DRE-T3 read from the waveform memory 14A is applied to the other input terminal of the gate G4.
[0027]
Timing clocks output from the gates G1 and G3 are applied to the set input terminal S of the SR flip-flop SR-FF through the OR gate OR1. The timing clock selected and taken out by the gates G2 and G4 is applied to the reset input terminal R of the SR flip-flop SR-FF through the OR gate OR2.
FIG. 2 shows the state of the waveform generation control signals DRE-L1, DRE-L3, DRE-T1, and DRE-T3 stored in the waveform memory 14A. In the waveform memory 14A, a storage area to be read is selected by a mode switching signal MS set in the register RG, and each waveform of the RZ waveform mode, the NRZ waveform mode, and the DNRZ waveform mode is selected. The logical values of the waveform generation control signals DRE-L1, DRE-L3, DRE-T1, and DRE-T3 used in the mode are read out.
[0028]
Here, in the RZ waveform mode and the NRZ waveform mode, for example, the driver control signal having the RZ waveform and the driver control signal DRE having the NRZ waveform mode are generated by the same operation as shown in FIGS. When the select signal SEL set in the register RG is “0” logic, the upper part of the table shown in FIG. 2 is read, and at this time, the pattern data is read according to the logic of DRE1. When the select signal SEL is "1" logic, the lower part of the table shown in FIG.
In the DNRZ waveform mode, the pattern data DRE1 and DRE2 are given to the waveform memory 14A regardless of the select signal SEL, and the DNRZ waveform mode is generated by the 2-bit signal of these pattern data DRE1 and DRE2. The stored memory is read.
[0029]
In the RZ waveform mode and the NRZ waveform mode, the driver control signal DRE for the RZ waveform mode and the NRZ waveform mode is generated by the same operation as shown in FIGS. On the other hand, in the DNRZ waveform mode, the waveform generation control signals DRE-L1, DRE-L3, DRE-T1, DREZ from the storage area of the DNRZ waveform mode according to the logical values of the pattern data DRE1 and DRE2. Each logical value of DRE-T3 is read.
FIG. 3 shows an operation example of the DNRZ waveform mode. FIG. 3A shows a setting example of the pattern data DRE1 and DRE2. FIG. 3B shows respective logic waveforms of the waveform generation control signals DRE-L1, DRE-L3, DRE-T1, and DRE-T3 obtained in the setting example of the pattern data DRE1 and DRE2 shown in FIG. 3A. FIG. 3C shows an example of timing clocks output from the timing generators 13A and 13B.
[0030]
3D shows a timing clock selectively taken out by the gates G1, G2, G3 and G4, and FIG. 3E shows a timing clock supplied to the set input terminal S and the reset input terminal R of the SR flip-flop SR-FF. . FIG. 3F shows the waveform of the driver control signal DRE generated from the SR flip-flop SR-FF. The driver control signal DRE shown in FIG. 3F can repeat “1” and “0” within the cycle of the test cycle, and the operation mode of the driver 16 can be switched at high speed.
[0031]
FIG. 4 shows the configuration of a driver control signal generation circuit proposed in claim 2 of the present invention. The driver control signal generation circuit shown in FIG. 4 has only a single DNRZ waveform mode that can be generated. When used as an IC test apparatus for testing only in this DNRZ waveform mode, the configuration is simple, so that an advantage that it can be manufactured at a low cost is obtained.
The driver control signal generation circuit 24 proposed in claim 2 of the present invention includes a first pulse generating circuit 24A that generates a pulse at the rising timing of the clock CLK, and a second pulse that generates a pulse at the falling timing of the clock CLK. , And OR of the pulses generated by the first pulse circuit 24A and the second pulse circuit 24B is performed by OR gates OR1 and OR2, and this logical sum pulse train PE is formed by gates G1 and G2. Intermittent control is performed according to the logic state of the driver control signal DREON / OFF, and the pulse train PE that is logically summed is input to the set input terminal S of the SR flip-flop SR-FF during the period when the driver on / off control signal DREON / OFF is H logic. During the period when the driver on / off control signal DReon / OFF is L logic, The input to the reset terminal R of R flip-flop SR-FF.
[0032]
This is shown in FIG. 5A shows the clock CLK, and FIG. 5B shows the driver on / off control signal DReon / OFF. The first pulsing circuit 24A outputs a pulse PC at the rising timing of the clock CLK as shown in FIG. 5C, and the second pulsing circuit 24B outputs the pulse PD at the falling timing of the clock CLK as shown in FIG. 5D. Output.
These pulses are ORed with the OR gates OR1 and OR2 to obtain a pulse train PE shown in FIG. 5E. The ORed pulse train PE is supplied to the gates G1 and G2. The gate G1 is controlled to open when the driver on / off control signal DREON / OFF is H logic, and outputs the pulse train PE-1 shown in FIG. 5F from the gate G1, and this pulse train PE-1 is output to the SR flip-flop. Input to the set input terminal S of the SR-FF.
[0033]
The gate G2 is controlled to open when the driver control signal DREON / OFF is L theory, and the pulse train PE-2 shown in FIG. 2G is output from the gate G2, and this pulse train PE-2 is output to the SR flip-flop SR- Input to the reset terminal R of the FF. A DC voltage VH corresponding to H logic is applied to the data input terminal D of the SR flip-flop SR-FF.
With this configuration, the SR flip-flop SR-FF has the gate G1 regardless of whether the clock CLK rises or falls immediately after the driver on / off control signal DREON / OFF rises to H logic. Therefore, the pulse train PE-1 (FIG. 5F) is always supplied to the set terminal S, the voltage VH supplied to the data input terminal D is read, and the driver control signal DRE (FIG. 5H) rises to H logic.
[0034]
Since the gate G2 is opened when the driver on / off control signal DREON / OFF falls to L logic, the clock CLK rises or falls immediately after that at the reset terminal R of the SR flip-flop SR-FF. The pulse train PE-2 (FIG. 5G) is input, the SR flip-flop SR-FF is reset, and the driver control signal DRE falls to L logic.
As described above, according to this embodiment, the SR flip-flop SR-FF can be set and reset at any timing of the rising edge or the falling edge of the clock CLK. It is possible to obtain the driver control signal DRE that is not greatly delayed from the / OFF timing by more than a half cycle of the clock CLK.
[0035]
In this embodiment, however, pulses are applied to the set input terminal S and the reset input terminal R of the SR flip-flop SR-FF at both the rising and falling timings of the clock CLK. SR-FF can be set and reset. As a result, as shown in FIG. 6B, even if one cycle T of the driver on / off control signal DREON / OFF is brought close to one cycle of the clock CLK in order to operate at high speed, the SR flip-flop SR-FF receives the H clock CLK. It can be set and reset at any timing of rising and falling. Therefore, in the example shown in FIG. 6, the driver 16 can be switched between the output mode and the high impedance mode every half cycle of the clock CLK. Therefore, there is an advantage that even a device operating at twice the speed of the clock CLK can be tested.
[0036]
FIG. 7 shows an embodiment of the first pulsing circuit 24A. The first pulsing circuit 24A is configured to generate a pulse at the rising timing of the clock CLK. For this reason, the example shown in FIG. 7 shows a case where the first pulsing circuit 24A is constituted by an AND gate AND and an inverter INV. The clock DLK is directly supplied to one input terminal of the AND gate AND, and the clock CLK / whose polarity is inverted through the inverter INV is input to the other input terminal of the AND gate AND.
[0037]
With this configuration, the AND gate AND input terminal is supplied with the clock CLK / whose polarity is inverted by being slightly delayed by the inverter INV with respect to the directly applied clock CLK. The AND outputs a pulse PE having a pulse width corresponding to the delay time τ of the inverter INV.
[0038]
【The invention's effect】
As described above, according to the present invention, it is possible to generate a driver control signal that is switched at high speed, so that it is possible to obtain an advantage of testing a memory that operates, for example, in the Double Data Rate system. In particular, according to the driver control signal generation circuit proposed in claim 1, in addition to the RZ waveform mode and the NRZ waveform mode, the driver control signals for various waveform modes of the DNRZ waveform mode capable of high-speed operation. Since the two timing generators 13A and 13B suffice while having a function capable of generating a high-performance IC, there is an advantage that a high-function IC test apparatus can be configured while suppressing an increase in cost.
[0039]
According to the driver control signal generation circuit proposed in claim 2 of the present invention, the only waveform mode that can be generated is the DNRZ waveform mode that operates at high speed. If it is applied to the case of providing a low-cost IC test apparatus, an inexpensive IC test apparatus can be provided.
[Brief description of the drawings]
FIG. 1 is a block diagram for explaining an embodiment of a driver control signal generation circuit proposed in claim 1 of the present invention;
FIG. 2 is a diagram for explaining the operation of FIG. 1;
FIG. 3 is a timing chart for explaining the operation of FIG. 1;
FIG. 4 is a block diagram for explaining an embodiment of a driver control signal generation circuit proposed in claim 2 of the present invention;
FIG. 5 is a timing chart for explaining the operation of FIG. 4;
6 is a timing chart similar to FIG.
7 is a block diagram for explaining an embodiment of the pulsing circuit used in FIG. 4;
FIG. 8 is a block diagram for explaining the outline of the IC test apparatus.
FIG. 9 is a block diagram for explaining a conventional driver control signal generation circuit;
10 is a diagram for explaining the operation of FIG. 9;
11 is a timing chart for explaining an operation of generating a waveform of an RZ waveform mode in the driver control signal generation circuit shown in FIG. 9;
12 is a timing chart for explaining the operation of generating another waveform mode in the circuit shown in FIG. 9;
13 is a timing chart for explaining an operation of generating a waveform of NRZ waveform mode in the circuit shown in FIG. 9;
14 is a timing chart for explaining still another example of the waveform generation mode shown in FIG.
FIG. 15 is a block diagram for explaining another example of a conventional driver control signal generation circuit;
16 is a diagram for explaining the operation of the driver control signal generation circuit shown in FIG. 15;
FIG. 17 is a timing chart for explaining an operation of generating an RZ waveform mode waveform by the driver control signal generation circuit shown in FIG. 15;
FIG. 18 is a timing chart for explaining the operation of generating the NRZ waveform mode waveform by the driver control signal generation circuit shown in FIG. 15;
FIG. 19 is a timing chart for explaining an operation of generating a high-speed DNRZ waveform mode waveform by the driver control signal generation circuit shown in FIG. 15;
[Explanation of symbols]
13, 13A, 13B Timing generator
14 Waveform formatter
14A waveform memory
16 drivers
17 Voltage comparator
19 Device under test
24 Driver control signal generation circuit
G1 to G4 gate
SR-FF SR flip-flop
LCK, TCK Timing clock

Claims (2)

A pair of pulsing circuits that generate pulses at the rising and falling timings of the input reference clock; and
Each of the pulse trains obtained from the pair of pulsing circuits is input, and two OR circuits for outputting the logical sum thereof;
A first AND circuit to which an output of one of the OR circuits and a driver on / off control signal are input;
A second AND circuit to which an output of the other OR circuit and an inverted signal of the driver on / off control signal are input;
The output of the first AND circuit is input to a set input terminal, and the output of the second AND circuit is input to a reset input terminal to generate a driver control signal that controls the driver in an output mode and a high impedance mode. SR flip-flop,
A driver control signal generation circuit comprising: In an IC test apparatus that applies a test pattern signal to a device under test through a driver, compares the response signal of the device under test with an expected value, and determines pass / fail of the device under test according to the comparison result.
An IC test apparatus, wherein a driver control signal is applied from any one of the driver control signal generation circuits according to claim 1 to a control input terminal of the driver.

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