JP5119255B2 - Test apparatus, test method, and manufacturing method - Google Patents

Description

The present invention relates to a test apparatus and a test method. In particular, the present invention relates to a test apparatus and a test method for testing a device under test such as a semiconductor circuit, and a method for manufacturing an electronic device using the test method. This application is related to the following international applications: For designated countries where incorporation by reference of documents is permitted, the contents described in the following application are incorporated into this application by reference and made a part of this application.
Application number PCT / JP2007 / 0666104 Filing date August 20, 2007

  As a test device for testing devices under test such as semiconductor circuits, the pass / fail and rank of the device under test is determined by whether the timing information of the signal under test output from the device under test matches the expected timing conditions. Devices that do this are known. For example, a logical value of each bit of the signal under measurement is detected according to a strobe signal (hereinafter referred to as an edge strobe) synchronized with the bit rate of the signal under measurement, and the detected logical pattern is compared with an expected value pattern. A test apparatus is known (see, for example, Patent Document 1).

There is also known a test apparatus that generates a plurality of continuous strobe signals (hereinafter referred to as multi-strobe) in each cycle of the signal under measurement and detects the edge position of the signal under measurement (see, for example, Patent Document 2). ). In this case, the quality of the device under test can be determined, for example, based on whether or not the edge position is within a predetermined range.
JP-A-2005-293808 JP 2004-125573 A

  In order to perform various tests on the device under test, the test apparatus preferably has the two functions described above. However, the expected value, control information, and the like to be used differ between when the test is performed using the edge strobe and when the test is performed using the multi-strobe. In general, an expected value used for a test is stored in advance in a memory. For this reason, when the above-described two functions are provided in the test apparatus, a memory and its control system are provided for each function, and the apparatus cost and power consumption increase.

  Therefore, an object of the present invention is to provide a test apparatus, a test method, and a manufacturing method that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.

  In order to solve the above-described problem, in a first embodiment of the present invention, a test apparatus for testing a device under test, wherein the test apparatus determines whether the value of the output signal of the device under test at a sequentially designated reference timing is good or bad. Edge strobe mode that determines the output signal value based on the expected value information, and a multi-point that determines whether the value of the output signal in the plurality of strobes for each reference timing is based on the expected value information. Based on whether the edge strobe mode or the multi-strobe mode is selected, the given expected value pattern is changed to the expected value information for the edge strobe mode or the expected value for the multi-strobe mode. Test apparatus including a conversion control unit for converting to any of value information To provide.

  According to a second aspect of the present invention, there is provided a test method for testing a device under test, wherein an edge strobe is used for determining whether a value of an output signal of a device under test at a sequentially designated reference timing is good or not based on expected value information. The mode and two operation modes of the multi-strobe mode for determining the quality of the output signal value in the plurality of strobes for each reference timing based on the expected value information, which is generated based on each reference timing, Based on whether the edge strobe mode or multi-strobe mode is selected, a test method for converting a given expected value pattern into either expected value information for edge strobe mode or expected value information for multi-strobe mode provide.

  According to a third aspect of the present invention, there is provided a manufacturing method for manufacturing an electronic device, the step of forming the electronic device, the step of testing the electronic device by the test method of the second aspect, and the test of the electronic device. A method of manufacturing an electronic device is provided by sorting non-defective electronic devices and / or ranking them according to electrical characteristics based on the results.

  The above summary of the invention does not enumerate all necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

It is a figure which shows an example of a structure of the test apparatus 10 which concerns on one embodiment of this invention. It is a figure explaining an example of edge strobe mode and multi-strobe mode. It is a figure which shows an example of the structure which transmits expected value information between the WF memory 190, the waveform shaping part, the edge strobe part 140, and the multi-strobe part 160. It is a figure which shows an example of a structure of the edge strobe part. It is a figure which shows an example of a response | compatibility with an expected value pattern and the expected value information in edge strobe mode. 3 is a diagram illustrating an example of a configuration of a multi-strobe unit 160. FIG. It is a figure which shows an example of a response | compatibility with an expected value pattern and the expected value information in multi-strobe mode. FIG. 3 is a diagram illustrating another configuration example of the test apparatus 10. It is a figure explaining the operation example of the test apparatus 10 demonstrated in relation to FIG. FIG. 26 is a diagram illustrating an example of the configuration of a computer 1900.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Test apparatus, 100 ... Site control part, 102 ... Mode selection part, 104 ... Conversion control part, 110 ... Pattern generation part, 120 ... Waveform shaping part, 122 ... TG circuit, 124, 126 ... delay circuit for timing adjustment, 140 ... edge strobe unit, 142 ... timing comparison unit, 144 ... logic comparison unit, 146 ... result delay unit, 160 ..Multi-strobe unit, 162... Sampling unit, 164... Output signal side delay circuit, 166... Strobe side delay circuit, 168... Acquisition unit, 170. 174 ... AND circuit, 176 ... selection unit, 178 ... determination unit, 180 ... result selection unit, 190 ... WF memory, 192 ... test signal supply unit, 194 ..Level comparison unit, 196 ... capture memory, 200 ... device under test, 1900 ... computer, 2000 ... CPU, 2010 ... ROM, 2020 ... RAM, 2030 ... communication Interface, 2040 ... Hard disk drive, 2050 ... FD drive, 2060 ... CD-ROM drive, 2070 ... I / O chip, 2075 ... Graphic controller, 2080 ... Display device, 2082 ... Host controller, 2084 ... I / O controller, 2090 ... Flexible disk, 2095 ... CD-ROM

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 is a diagram illustrating an example of a configuration of a test apparatus 10 according to an embodiment of the present invention. The test apparatus 10 is an apparatus for testing a device under test 200 such as a semiconductor circuit, and has two operation modes of an edge strobe mode and a multi-strobe mode. First, the outline of the edge strobe mode and the multi-strobe mode will be described, and the configuration and operation of the test apparatus 10 will be described later.

  FIG. 2 is a diagram for explaining an example of the edge strobe mode and the multi-strobe mode. In both modes, the test apparatus 10 generates level comparison result signals SH and SL by comparing the signal level of the output signal Vout of the device under test 200 with the threshold value VOH and the threshold value VOL, respectively. For example, the level comparison result signal SH is a signal indicating by a binary logical value whether or not the signal level of the output signal Vout is higher than the threshold value VOH.

  In the edge strobe mode, the test apparatus 10 generates a single strobe pulse for each test period and detects the logical value of the output signal Vout. The test apparatus 10 of this example samples the level comparison result signals SH and SL with the edge strobe ESTRB corresponding to the reference timing. As an example, the edge strobe ESTRB may be arranged at approximately the center of each cycle of the output signal Vout. Next, the test apparatus 10 determines whether or not the logical value of the sampled output signal Vout matches the expected value. Thereby, the test apparatus 10 determines whether or not the logical value of the output signal Vout matches the expected value at a single timing in each cycle of the output signal Vout.

  In the multi-strobe mode, the test apparatus 10 specifies a transition timing of the logical value of the output signal Vout by generating a plurality of continuous strobe pulses for each test cycle. The test apparatus 10 of this example samples the level comparison result signals SH and SL at a plurality of points for each test cycle with the multi-strobe MSTRB corresponding to the reference timing. The multi-strobe MSTRB may be arranged near the edge of the output signal in each cycle section of the output signal Vout. The reference timing may be a timing designated for each test cycle.

  The test apparatus 10 samples the level comparison result signals SH and SL with each of the plurality of strobes included in the multi-strobe MSTRB. The edge position of the output signal is specified from a plurality of sampled logical values. The test apparatus 10 generates sampling signals MFH and MFL obtained by sampling both the level comparison result signals SH and SL with the multi-strobe MSTRB. The test apparatus 10 calculates the edge position of the output signal from one of the sampling signals MFH and MFL, and determines whether it is within a predetermined range. Thereby, the test apparatus 10 specifies the edge position of the output signal, and determines pass / fail based on the edge position.

  Next, the configuration and operation of the test apparatus 10 shown in FIG. 1 will be described. The test apparatus 10 includes a site control unit 100, a pattern generation unit 110, a WF memory 190, a waveform shaping unit 120, a test signal supply unit 192, a level comparison unit 194, an edge strobe unit 140, a multi-strobe unit 160, a result selection unit 180, In addition, a capture memory 196 is provided.

  The site control unit 100 controls the test apparatus 10. The site control unit 100 is, for example, a workstation or the like, and may control the test apparatus 10 according to a test program given from a user or the like. For example, the site controller 100 may operate the pattern generator 110 according to the test program. The site control unit 100 includes a mode selection unit 102 and a conversion control unit 104 described later.

  The pattern generation unit 110 generates a test pattern and an expected value pattern based on data or the like given from the site control unit 100. The test pattern is, for example, a pattern that specifies a logic pattern that a test signal input to the device under test 200 should have, a logic pattern that a control signal input to the device under test 200 should have, timing information such as a test signal, and the like. It's okay. The expected value pattern may be a pattern indicating an expected value for the output signal of the device under test 200.

  The WF memory 190 outputs a logic pattern corresponding to a given test pattern. For example, the WF memory 190 may store a logical pattern in each address in advance, and sequentially output the logical pattern of the address sequentially designated by the test pattern as the logical pattern of the test signal.

  The WF memory 190 functions as a conversion unit that converts a given expected value pattern into expected value information. Here, the expected value information may be information including an expected value to be compared with the logical value of the output signal, for example. The expected value information may include information used for signal processing in the edge strobe unit 140 and the multi-strobe unit 160. For example, the WF memory 190 may store each expected value information in advance in association with each expected value pattern, and output the expected value information corresponding to the expected value pattern input from the pattern generation unit 110.

  The waveform shaping unit 120 shapes the waveform of the test signal based on the logic pattern output from the WF memory 190. In addition, the waveform shaping unit 120 may determine the edge position of the test signal based on the timing information included in the test pattern. Further, the waveform shaping unit 120 supplies the expected value information output from the WF memory 190 to at least one of the edge strobe unit 140 and the multi-strobe unit 160. The waveform shaping unit 120 may supply expected value information for each cycle of the output signal of the device under test 200.

  The test signal supply unit 192 receives the test signal output from the waveform shaping unit 120, converts the test signal to an analog voltage having a predetermined amplitude, and supplies the analog voltage to the device under test 200. The test signal supply unit 192 may include a driver that outputs a voltage corresponding to the logical value of the test signal.

  The device under test 200 operates in response to a given test signal and outputs an output signal. When the device under test 200 is a semiconductor memory, a write / read test is performed on an address specified by a test signal. When the device under test 200 is a general integrated circuit, a test corresponding to the integrated circuit is performed.

  The level comparison unit 194 outputs a comparison result obtained by comparing the signal level of the output signal of the device under test 200 with a predetermined threshold value. For example, the level comparison unit 194 may output the level comparison result signal SH indicating the H logic when the signal level of the output signal is greater than the predetermined threshold VOH and indicating the L logic when it is smaller than the threshold VOH. The level comparison unit 194 may output a level comparison result signal SL indicating H logic when the signal level of the output signal is smaller than a predetermined threshold VOL, and indicating L logic when larger than the threshold VOL. Here, it is assumed that the threshold value VOH is larger than the threshold value VOL. As a result, the analog waveform of the output signal of the device under test 200 is converted into a binary logic waveform.

  The edge strobe unit 140 acquires a logical value at a designated reference timing for the output signal of the device under test 200. The edge strobe unit 140 performs the sampling operation in the edge strobe mode described with reference to FIG. The edge strobe unit 140 in this example samples the logical value of the output signal at the reference timing by sampling the level comparison result signals SH and SL output from the level comparison unit 194 at the reference timing. The edge strobe unit 140 may generate a sampling signal FH and a sampling signal FL obtained by sampling the level comparison result signal SH using the threshold value VOH and the level comparison result signal SL using the threshold value VOL at the reference timing.

  The test apparatus 10 may further include a timing generation unit (not shown) that generates a reference timing (or edge strobe ESTRB). In another example, the edge strobe unit 140 may acquire the signal level of the output signal using an AD converter or the like instead of the logical value of the output signal at the reference timing.

  The edge strobe unit 140 determines pass / fail based on the sampling signal as the acquisition result and the expected value information provided from the waveform shaping unit 120. For example, the edge strobe unit 140 may determine the quality of the acquisition result based on whether the value of the sampling signal matches the expected value indicated in the expected value information. Expected value information at the time of edge strobe is, for example, 1-bit data.

  As an example, if the logic value of the output signal is H logic, the pattern generator 110 outputs an expected value pattern indicating H logic. The WF memory 190 functioning as a conversion unit generates expected value information indicating an expected value for the sampling signal FH and an expected value for the sampling signal FL from the expected value pattern. Then, the edge strobe unit 140 determines that the output signal value acquisition result is good when both the sampling signal FH and the sampling signal FL coincide with the expected value.

  The multi-strobe unit 160 samples a plurality of points with respect to the output signal at the timing of a plurality of strobes (hereinafter referred to as multi-strobe) generated with reference to the reference timing. For example, the multi-strobe unit 160 may sample the level comparison result signals SH and SL output from the level comparison unit 194 at a plurality of strobe timings where the phase difference with respect to the reference timing gradually changes. The multi-strobe unit 160 may generate a sampling signal MFH and a sampling signal MFL obtained by sampling the level comparison result signal SH and the level comparison result signal SL at the multi-strobe timing.

  The multi-strobe unit 160 determines the quality of the output signal value acquisition result based on the expected value information given from the waveform shaping unit 120. The multi-strobe unit 160 performs the multi-strobe mode sampling operation described in FIG. As an example, the multi-strobe unit 160 selects a sampling signal specified by expected value information from the sampling signal MFH and the sampling signal MFL. For example, when the sampling signal MFH is selected, the pattern generation unit 110 outputs an expected value pattern indicating H logic. The WF memory 190 functioning as a conversion unit generates expected value information specifying the sampling signal MFH from the expected value pattern. The expected value information at the time of multi-strobe is, for example, 4-bit code data when the multi-strobe unit 160 is configured to acquire 16 points. The 4-bit code data may be used by holding the code value in the WF memory 190 or the waveform shaping unit 120.

  Further, the multi-strobe unit 160 may calculate the edge position of the output signal from the selected sampling signal. Then, the multi-strobe unit 160 determines the quality of the output signal value acquisition result based on whether or not the calculated edge position is within a predetermined range. For example, the multi-strobe unit 160 can determine the quality of the acquisition result by the processing as described above.

  As described above, even when the pattern generation unit 110 outputs the same expected value pattern, the expected value information to be used in the edge strobe unit 140 operating in the edge strobe mode and the multi-strobe unit 160 operating in the multi-strobe mode are used. It may be different from the expected value information. Therefore, the WF memory 190 functioning as a conversion unit switches and outputs expected value information depending on whether it operates in the edge strobe mode or the multi-strobe mode.

  In this example, the mode selection unit 102 selects one of the edge strobe mode and the multi-strobe mode. The mode selection unit 102 may select any mode according to a test program given by a user or the like. The mode selection unit 102 notifies the selection result to the conversion control unit 104 and the result selection unit 180.

  Based on whether the edge strobe mode or the multi-strobe mode is selected, the conversion control unit 104 outputs an expected value pattern to the WF memory 190 functioning as a conversion unit, expected value information for the edge strobe unit 140, or It is converted into one of the expected value information for the multi-strobe unit 160. For example, when the mode selection unit 102 selects the edge strobe mode, the conversion control unit 104 writes each expected value information for the edge strobe unit 140 corresponding to each expected value pattern in the WF memory 190 in advance, and sets the multi-strobe mode. When selecting, each expected value information for the multi-strobe unit 160 corresponding to each expected value pattern may be written in the WF memory 190 in advance.

  Thereby, the expected value information output from the WF memory 190 can be switched according to the mode. In addition, since the expected value information of the mode not in use is not stored, the capacity of the WF memory 190 can be reduced.

  Further, the conversion control unit 104 may write the expected value information of the same bit length in the WF memory 190 as the expected value information for the edge strobe unit 140 and the expected value information for the multi-strobe unit 160. Then, the waveform shaping unit 120 may supply the expected value information output from the WF memory 190 to the edge strobe unit 140 and the multi-strobe unit 160 in parallel. In this case, a strobe unit that does not correspond to the selected mode may output a determination result corresponding to the expected value information. However, since the expected value information does not correspond to the strobe part, the strobe part may not output the determination result, or may mask each bit of the determination result with a predetermined logical value.

  The result selection unit 180 selects the determination result output by the edge strobe unit 140 when the edge selection mode is selected by the mode selection unit 102, and the multi-strobe unit 160 when the multi-strobe mode is selected. Select the judgment result output by. With such a configuration, it is possible to easily obtain the determination result of the mode that is not selected.

  The capture memory 196 stores the determination result selected by the result selection unit 180. Further, when the device under test 200 is a semiconductor memory, the capture memory 196 has the same memory capacity as the address space of the semiconductor memory, and performs cumulative addition to the address space corresponding to the address of the semiconductor memory to be read. It may be configured. According to the test apparatus 10 described above, a test apparatus having an edge strobe mode and a multi-strobe mode can be realized with a small circuit configuration. For this reason, apparatus cost can be reduced and power consumption can be reduced.

  FIG. 3 is a diagram illustrating an example of a configuration for transmitting expected value information among the WF memory 190, the waveform shaping unit 120, the edge strobe unit 140, and the multi-strobe unit 160. The test apparatus 10 of this example further includes a TG circuit 122-1, a TG circuit 122-2, and timing adjustment delay circuits 124-1, 124-2, 126-1 and 126-2.

  The WF memory 190 outputs expected value information corresponding to the expected value pattern received from the pattern generator 110. The expected value information of this example has 4 bits of EXPH, EXPHZ, EXPL, and EXPLZ.

  The TG circuit 122-1 receives 2 bits (EXPH, EXPHZ) of the expected value information. Further, the TG circuit 122-2 receives the other two bits (EXPL, EXPLZ) of the expected value information. Each TG circuit 122 outputs expected value information obtained by adding new 2-bit information corresponding to the received 2-bit information. For example, the TG circuit 122-1 outputs 4 bits of EXPH, EXPHZ, OEPNH, and STRBH. The TG circuit 122-2 outputs 4 bits of EXPL, EXPLZ, OPENL, and STRBL. Further, the TG circuit 122 may generate the bits of OPENH / L and STRBH / L according to the applied mask signal MTV.

  The waveform shaping unit 120 outputs a waveform corresponding to each bit of expected value information output from the TG circuits 122-1 and 122-2. For example, the waveform shaping unit 120 may have a plurality of output ports provided in parallel corresponding to each bit of the expected value information. When the logical value of each bit of the expected value information is 1, the waveform shaping unit 120 may output one pulse from the output port corresponding to the bit.

  As described above, the edge strobe unit 140 and the multi-strobe unit 160 may receive the expected value information output from the waveform shaping unit 120 in parallel. Further, the edge strobe unit 140 and the multi-strobe unit 160 may receive the output signal of the device under test in parallel and output the pass / fail judgment result in parallel.

  Note that STRBH and STRBL output by the waveform shaping unit 120 define reference timings in the edge strobe unit 140 and the multi-strobe unit 160. For example, STRBH may define a reference timing for sampling the level comparison result signal SH, and STRBL may define a reference timing for sampling the level comparison result signal SL. The waveform shaping unit 120 of this example has a function as a timing generation unit that generates a reference timing and supplies the reference timing to each strobe unit.

  The timing adjustment delay circuits 124-1, 124-2, 126-1 and 126-2 each delay the STRBH and STRBL input to the edge strobe unit 140 and the multi-strobe unit 160, respectively, so that each strobe is delayed. The reference timing for each level comparison result signal SH, SL in the unit is adjusted.

  The delay information for delaying the timing adjustment delay circuit 124 and the timing adjustment delay circuit 126 may be provided in advance in the waveform shaping unit 120 as timing information. A plurality of sets of timing information provided in the waveform shaping unit 120 are provided by, for example, a memory, and are switched by a timing set signal TS (not shown) received from the pattern generation unit 110, whereby the timing adjustment delay circuit 124 and timing adjustment are provided. The delay amount of the delay circuit 126 may be set in real time.

  Thereby, the strobe timing of the edge strobe ESTRB and the multi-strobe MSTRB shown in FIG. 2 can be set in real time by the timing set signal TS. In addition, since the strobe operation in both the edge strobe mode and the multi-strobe mode can be selectively switched, the test can be easily performed from a semiconductor memory to various integrated circuits.

  FIG. 4 is a diagram illustrating an example of the configuration of the edge strobe unit 140. The edge strobe unit 140 includes a timing comparison unit 142-1, a timing comparison unit 142-2, a logic comparison unit 144, a result delay unit 146-1, and a result delay unit 146-2.

  The timing comparison unit 142-1 acquires the logical value FH of the level comparison result signal SH in accordance with the STRBH pulse. In addition, the timing comparison unit 142-2 acquires the logical value FL of the level comparison result signal SL in accordance with the STRBL pulse. The timing comparison unit 142-1 and the timing comparison unit 142-2 may take in the logical values of the level comparison result signals SH and SL on condition that the input OPENH or OPENL indicates L logic. Further, the timing comparison unit 142-1 and the timing comparison unit 142-2 may be flip-flops that receive the level comparison result signals SH and SL at signal input terminals and receive STRBH / L at a clock input terminal.

  The logical comparison unit 144 determines whether or not the logical values FH and FL acquired by the timing comparison unit 142-1 and the timing comparison unit 142-2 match the logical values defined by the expected value information EXPH, EXPHZ, EXPL, and EXPLZ. And the logical comparison result signals HR and LR are output.

  The result delay unit 146 delays the determination result (logic comparison result signal HR / LR) output from the edge strobe unit 140 and inputs the result to the result selection unit 180. The result delay unit 146 may be a circuit in which a number of flip-flops corresponding to the delay amount to be generated are cascade-connected. A reference clock that defines the operation cycle of the test apparatus 10 may be input to each flip-flop of the result delay unit 146. Thereby, a delay of an integral multiple of the period of the reference clock can be generated.

  As described with reference to FIG. 2, the edge strobe unit 140 and the multi-strobe unit 160 have different processes for the input level comparison result signals SH and SL. For this reason, the processing times in the edge strobe unit 140 and the multi-strobe unit 160 are different, and the respective determination results may not be input to the result selection unit 180 at the same time. The result delay unit 146 may delay the determination result output from the edge strobe unit 140 so as to cancel the difference in processing time so that the respective determination results are simultaneously input to the result selection unit 180.

  FIG. 5 is a diagram illustrating an example of a correspondence between an expected value pattern and expected value information in the edge strobe mode. In the edge strobe mode, the pattern generation unit 110 generates a pattern indicating one of L, H, Z, X, ZINV, and Tr as an expected value pattern. The pattern generator 110 may output the expected value pattern as 4-bit data.

  For example, the expected value pattern L is an expected value for determining that the logical value of the output signal is L. When the logical value of the output signal is not L, the logical comparison unit 144 may output a logical comparison result signal LR indicating a “1” failure. The logic comparison unit 144 may determine whether or not the logic value of the output signal is L based on the logic value FL. When the expected value pattern is L, the logical comparison unit 144 may output the logical comparison result signal HR indicating “0” regardless of the logical value FH. The logical comparison unit 144 performs logical operations on the logical values FH and FL and the expected value information EXPH, EXPHZ, EXPL, and EXPLZ, thereby generating logical comparison result signals HR and LR. The WF memory 190 outputs expected value information EXPH, EXPHZ, EXPL, EXPLZ that causes the logical comparison unit 144 to operate as described above for the expected value pattern.

  The expected value pattern H is an expected value for determining that the logical value of the output signal is H. When the logical value of the output signal is not H, the logical comparison unit 144 may output the logical comparison result signal HR indicating “1” failure. The logic comparison unit 144 may determine whether the logic value of the output signal is H based on the logic value FH. When the expected value pattern is H, the logic comparison unit 144 may output the logic comparison result signal LR indicating “0” regardless of the logic value FL. Even in this case, the WF memory 190 outputs the expected value information EXPH, EXPHZ, EXPL, EXPLZ for operating the logical comparison unit 144 as described above for the expected value pattern.

  The expected value pattern X is an expected value to which the logical comparison result signals HR and LR indicating “0” don't care should be output regardless of the logical value of the output signal. In this case, the logical comparison unit 144 outputs logical comparison result signals HR and LR indicating “0” regardless of the logical values FH and FL. Even in this case, the WF memory 190 outputs the expected value information EXPH, EXPHZ, EXPL, EXPLZ for operating the logical comparison unit 144 as described above for the expected value pattern.

  Further, the expected value patterns Z and ZINV are expected values for determining that the output impedance of the device under test 200 is in a predetermined state. The expected value Tr is an expected value for determining that the edge of the output signal has been sampled. Also in these cases, the WF memory 190 outputs expected value information EXPH, EXPHZ, EXPL, EXPLZ that causes the logical comparison unit 144 to operate according to the expected value pattern.

  Further, the waveform shaping unit 120 may generate STRBH / L and OPENH / L as shown in FIG. 5 based on the expected value information provided. By such an operation, the edge strobe unit 140 can perform processing in the edge strobe mode.

  FIG. 6 is a diagram illustrating an example of the configuration of the multi-strobe unit 160. The multi-strobe unit 160 includes a sampling unit 162, an encoder 170, an inverter 172, a logical product circuit 174, a selection unit 176, and a determination unit 178. The multi-strobe unit 160 includes a sampling unit 162, an encoder 170, an inverter 172, and an AND circuit 174 for each of the level comparison result signals SH and SL. In FIG. The sampling unit 162, the encoder 170, and the inverter 172 are omitted.

  The sampling unit 162 includes n (n is an integer of 2 or more) output signal side delay circuits 164, n strobe side delay circuits 166, and n acquisition units 168. The n output signal side delay circuits 164 are provided in cascade connection, and sequentially delay the output signal (in this example, the level comparison result signal SH / SL). The delay amount of each output signal side delay circuit 164 may be substantially the same. The sampling unit 162 receives the level comparison result signal SH and outputs n pieces of sampling data sampled at a substantially constant time interval.

  The plurality of strobe side delay circuits 166 are provided in one-to-one correspondence with the plurality of output signal side delay circuits 164. The plurality of strobe side delay circuits 166 are provided in cascade connection, and sequentially delay the input strobe signal STRBH / L (reference timing). The delay amount of each strobe side delay circuit 166 may be substantially the same. However, the delay amounts of the output signal side delay circuit 164 and the strobe side delay circuit 166 are different. By setting the delay so that the phase difference between the level comparison result signals SH and SL and the strobe signal gradually changes, the level comparison result signal SH can be sampled at substantially constant time intervals.

  The plurality of acquisition units 168 are provided in one-to-one correspondence with the plurality of output signal side delay circuits 164. Each acquisition unit 168 acquires the logical value of the level comparison result signals SH and SL output from the corresponding output signal side delay circuit 164 at the timing of the strobe signal output from the corresponding strobe side delay circuit. Each acquisition unit 168 may be a flip-flop.

  With such a configuration, the logical values of the level comparison result signals SH and SL are acquired with a plurality of strobes whose phases are gradually shifted according to the delay difference between the output signal side delay circuit 164 and the strobe side delay circuit 166. can do. Therefore, the edge position of the output signal can be detected from the position of the acquisition unit 168 where the logical value to be acquired transitions. The logical value output from each acquisition unit 168 is input to the encoder 170 as n pieces of sampling data.

  The encoder 170 converts the bit position where the logic value transitions in the n pieces of sampling data into encoded data represented by a binary number. Specifically, the encoder 170 receives sampling data, converts it into parallel data by retiming with an n-bit register, converts it into binary encoded data, and outputs it. With the encoded data, the edge position of the output signal can be specified as a code value. For example, when n is 15, the encoder 170 outputs 4-bit encoded data.

  The AND circuit 174-1 outputs a logical product of the encoded data output from the encoder 170 and the logical value output from the inverter 172. That is, the AND circuit 174-1 outputs the encoded data as “0” when the inverter 172 outputs L logic.

  The inverter 172 inverts a predetermined 1 bit out of the expected value information output from the waveform shaping unit 120 and outputs the result. The inverter 172 in this example inverts the EXPHZ (EXPLZ) bit of the expected value information and outputs it. For example, when EXPHZ of the expected value information is “1”, the inverter 172 outputs the data output from the AND circuit 174-1 so as not to perform pass / fail determination using the encoded data corresponding to the level comparison result signal SH. Mask to "0".

  The selection unit 176 selects and outputs one of the encoded data output from the logical product circuit 174-1 and the logical product circuit 174-2. The selection unit 176 selects the encoded data based on the EXPH / L bits from the expected value information output by the waveform shaping unit 120. The selection unit 176 may select encoded data corresponding to a bit indicating a predetermined logical value in EXPH / L.

  The determination unit 178 determines whether or not the measurement result of the output signal is good based on the encoded data output from the selection unit 176. For example, the determination unit 178 may determine pass / fail based on the result of comparing the code value of the encoded data with the code value for comparison.

  FIG. 7 is a diagram illustrating an example of a correspondence between an expected value pattern and expected value information in the multi-strobe mode. However, FIG. 7 shows EXPHZ and EXPH among the expected value information EXPHZ, EXPH, EXPLZ and EXPL stored in the WF memory 190. The WF memory 190 may store the same information as EXPHZ and EXPL as EXPLZ and EXPL.

  In the multi-strobe mode, the pattern generation unit 110 generates a pattern indicating any one of L, H, and X as an expected value pattern. The pattern generation unit 110 may output the expected value pattern as 2-bit data. However, since 2-bit data is similarly output for EXPLZ and EXPL, the pattern generator 110 outputs a 4-bit expected value pattern as in the edge strobe mode. Further, the TG circuit 122-1 shown in FIG. 3 generates STRBH and OPENH based on the applied mask signal MTV and EXPHZ and EXPH.

  The expected value pattern L indicates that, for example, the selection unit 176 selects the encoded data for the level comparison result signal SL and performs pass / fail judgment. The expected value pattern H indicates that the selection unit 176 selects the encoded data for the level comparison result signal SH and performs pass / fail judgment. Further, the expected value pattern X indicates that no pass / fail judgment is performed for any encoded data.

  When the mask signal is H logic, the TG circuit 122 outputs L logic as the STRB bit and outputs H logic as the OPEN bit. As a result, the reference timing is not input to the multi-strobe unit 160, and the output of the AND circuit 174 is masked by the inverter 172. Therefore, the multi-strobe unit 160 does not perform pass / fail determination based on the encoded data.

  Also, when the expected value pattern is X, the TG circuit 122 outputs L logic as the STRB bit and H logic as the OPEN bit. Thereby, the multi-strobe unit 160 does not perform pass / fail determination based on the encoded data. At this time, the WF memory 190 outputs data that causes the TG circuit 122 to perform the above-described operation as expected value information. In such a case, the WF memory 190 of this example outputs EXPHZ = 1, for example, and outputs arbitrary data as EXPH.

  When the expected value pattern is L or H, the WF memory 190 of this example outputs EXPHZ = 0, and outputs data corresponding to the expected value as EXPH. At this time, the TG circuit 122 outputs H logic as the STRB bit and outputs L logic as the OPEN bit. As a result, the multi-strobe unit 160 can perform the pass / fail determination by selecting the encoded data corresponding to the expected value information.

  As described above, the expected value information to be input to the edge strobe unit 140 and the multi-strobe unit 160 may be different even if the bit pattern of the expected value pattern is the same. Since the test apparatus 10 of this example changes the expected value information stored in the WF memory 190 depending on whether the operation mode is the edge strobe mode or the multi-strobe mode, the expected value information suitable for each mode is displayed. The edge strobe unit 140 and the multi-strobe unit 160 can be supplied.

  FIG. 8 is a diagram illustrating another configuration example of the test apparatus 10. The test apparatus 10 of this example is different from the configuration of the test apparatus 10 described with reference to FIG. 1 in that the edge strobe unit 140 is not provided. Other configurations may be the same as the configuration of the test apparatus 10 described with reference to FIG.

  The test apparatus 10 of this example acquires the value of the output signal in the multi-strobe unit 160 regardless of whether the edge strobe mode or the multi-strobe mode is selected. The multi-strobe unit 160 may have the configuration described in relation to FIG. Also in this example, the WF memory 190 converts the expected value pattern into expected value information for each mode and outputs it depending on whether the edge strobe mode or the multi-strobe mode is selected.

  The result selection unit 180 performs different processing on the data received from the multi-strobe unit 160 depending on whether the edge strobe mode or the multi-strobe mode is selected. In the multi-strobe mode, the result selection unit 180 may output the determination result received from the multi-strobe unit 160 to the capture memory 196 as it is. In the multi-strobe mode, the result selection unit 180 may select a determination result corresponding to a predetermined strobe from the determination results received from the multi-strobe unit 160 and output the determination result to the capture memory 196.

  FIG. 9 is a diagram illustrating an operation example of the test apparatus 10 described in relation to FIG. In this example, the timing at which the value of the output signal should be acquired in the edge strobe mode corresponds to the timing of the fourth strobe among the plurality of strobes in each test cycle.

  As described above, in the multi-strobe mode, the result selection unit 180 may output the determination result received from the multi-strobe unit 160 to the capture memory 196 as it is. In the edge strobe mode, the result selection unit 180 of this example may select a determination result corresponding to the fourth strobe from among the multi-strobes and output it to the capture memory 196. The result selection unit 180 may select strobes in the same order in each multi-strobe, or may select strobes in a different order in each multi-strobe.

  With such a configuration, the test apparatus 10 can operate in both the edge strobe mode and the multi-strobe mode without including the edge strobe unit 140 described with reference to FIG. For this reason, the circuit scale of the test apparatus 10 can be reduced.

  In the test apparatus 10 described with reference to FIGS. 1 to 9, the multi-strobe unit 160 may output the value of the output signal acquired according to the strobe. In this case, the result selection unit 180 may receive the expected value information and compare the value of the output signal with the expected value information.

  For example, in the edge strobe mode of the test apparatus 10 illustrated in FIG. 8, the result selection unit 180 includes a value corresponding to a strobe predetermined in each multi-strobe among values received from the multi-strobe unit 160, and expected value information. Outputs the result of the comparison. In the multi-strobe mode of the test apparatus 10 shown in FIG. 8, the result selection unit 180 outputs a determination result obtained by comparing each value received from the multi-strobe unit 160 with the expected value information.

  Further, the test method using the test apparatus 10 described with reference to FIGS. 1 to 9 can be applied to a manufacturing method for manufacturing an electronic device such as a semiconductor circuit. For example, the manufacturing method includes a step of forming an electronic device, a step of testing the formed electronic device by the method described with reference to FIGS. 1 to 9, and a non-defective electronic device based on a test result of the electronic device. Producing and / or manufacturing electronic devices by ranking according to electrical characteristics. Further, the manufacturing method may include a step of manufacturing an electronic device by eliminating electronic devices of defective products and / or non-standard rank products based on the test result of the electronic device.

  FIG. 10 is a diagram illustrating an example of the configuration of the computer 1900. The computer 1900 functions as a configuration of the test apparatus 10 described in FIGS. 1 to 9 or a part of the test apparatus 10 based on a given program. For example, the computer 1900 may function as the site control unit 100. In this case, the computer 1900 includes the pattern generation unit 110, the WF memory 190, the waveform shaping unit 120, the test signal supply unit 192, the level comparison unit 194, the edge strobe unit 140, the multi-strobe described with reference to FIGS. The unit 160, the result selection unit 180, and the capture memory 196 may be controlled. The program given to the computer 1900 may cause the computer 1900 to function as the mode selection unit 102 and the conversion control unit 104 described with reference to FIGS.

  A computer 1900 according to this embodiment includes a CPU peripheral unit, an input / output unit, and a legacy input / output unit. The CPU peripheral unit includes a CPU 2000, a RAM 2020, a graphic controller 2075, and a display device 2080 that are connected to each other by a host controller 2082. The input / output unit includes a communication interface 2030, a hard disk drive 2040, and a CD-ROM drive 2060 that are connected to the host controller 2082 by the I / O controller 2084. The legacy input / output unit includes a ROM 2010, an FD drive 2050, and an I / O chip 2070 connected to the I / O controller 2084.

  The host controller 2082 connects the RAM 2020 to the CPU 2000 and the graphic controller 2075 that access the RAM 2020 at a high transfer rate. The CPU 2000 operates based on programs stored in the ROM 2010 and the RAM 2020 and controls each unit. The graphic controller 2075 acquires image data generated by the CPU 2000 or the like on a frame buffer provided in the RAM 2020 and displays it on the display device 2080. Instead of this, the graphic controller 2075 may include a frame buffer for storing image data generated by the CPU 2000 or the like.

  The I / O controller 2084 connects the host controller 2082 to the communication interface 2030, the hard disk drive 2040, and the CD-ROM drive 2060 that are relatively high-speed input / output devices. The communication interface 2030 communicates with other devices via a network. For example, the communication interface 2030 may exchange data with the pattern generation unit 110, the WF memory 190, the result selection unit 180, the capture memory 196, and the like.

  The hard disk drive 2040 stores programs and data used by the CPU 2000 in the computer 1900. The CD-ROM drive 2060 reads a program or data from the CD-ROM 2095 and provides it to the hard disk drive 2040 via the RAM 2020.

  The I / O controller 2084 is connected to the ROM 2010, the FD drive 2050, and the relatively low-speed input / output device of the I / O chip 2070. The ROM 2010 stores a boot program that the computer 1900 executes at startup, a program that depends on the hardware of the computer 1900, and the like. The FD drive 2050 reads a program or data from the flexible disk 2090 and provides it to the hard disk drive 2040 via the RAM 2020. The I / O chip 2070 connects various input / output devices via the FD drive 2050, for example, a parallel port, a serial port, a keyboard port, a mouse port, and the like.

  A program provided to the hard disk drive 2040 via the RAM 2020 is stored in a recording medium such as the flexible disk 2090, the CD-ROM 2095, or an IC card and provided by the user. The program is read from the recording medium, installed in the hard disk drive 2040 in the computer 1900 via the RAM 2020, and executed by the CPU 2000.

  The program is installed in the computer 1900. The program works on the CPU 2000 or the like to cause the computer 1900 to function as the site control unit 100 described above.

  The program shown above may be stored in an external recording medium. As the recording medium, in addition to the flexible disk 2090 and the CD-ROM 2095, an optical recording medium such as DVD and CD, a magneto-optical recording medium such as MO, a tape medium, a semiconductor memory such as an IC card, and the like can be used. Further, a storage device such as a hard disk or a RAM provided in a server system connected to a dedicated communication network or the Internet may be used as a recording medium, and the program may be provided to the computer 1900 via the network.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  As described above, according to the embodiment of the present invention, it is possible to realize a test apparatus having both functions of the edge strobe mode and the multi-strobe mode. In addition, by reducing the capacity of the WF memory 190, the test apparatus can be realized at low cost.

Claims (13)

A test apparatus for testing a device under test,
The test apparatus is generated with reference to the edge strobe mode for determining the quality of the output signal value of the device under test at the sequentially designated reference timing based on expected value information, and the respective reference timings. Having two operation modes of a multi-strobe mode for determining the quality of the value of the output signal in a plurality of strobes for each reference timing based on expected value information;
Conversion that converts a given expected value pattern into expected value information for edge strobe mode or expected value information for multi-strobe mode based on whether the edge strobe mode or the multi-strobe mode is selected A test apparatus including a control unit. A conversion unit for converting the expected value pattern to be given into the expected value information and outputting the expected value information;
A mode selection unit that selects one of the edge strobe mode or the multi-strobe mode;
The conversion control unit, based on whether the mode selection unit selects the edge strobe mode or the multi-strobe mode, causes the conversion unit to send the expected value pattern to the expectation for the edge strobe mode. The test apparatus according to claim 1, wherein the value is converted into either value information or expected value information for the multi-strobe mode. The conversion unit stores the expected value pattern and the expected value information in association with each other, and outputs the expected value information corresponding to the expected value pattern that is input,
When the mode selection unit selects the edge strobe mode, the conversion control unit previously writes each expected value information for the edge strobe mode corresponding to each expected value pattern into a memory, and selects the multi-strobe mode. 3. The test apparatus according to claim 2, wherein in the case of performing, each expected value information for the multi-strobe mode corresponding to each expected value pattern is written in the memory in advance. The conversion control unit writes the expected value information having the same bit length in the memory as the expected value information for the edge strobe mode and the expected value information for the multi-strobe mode. Test equipment. An edge strobe unit that acquires the value of the output signal at a designated reference timing, and determines the quality of the acquired result based on given expected value information;
A multi-strobe that obtains the value of the output signal at the timing of a plurality of strobes for each reference timing generated based on each of the reference timings, and determines the quality of the obtained result based on the expected value information The test apparatus according to claim 4, further comprising: a section. The edge strobe unit and the multi-strobe unit receive the output signal of the device under test in parallel, receive the expected value information from the memory in parallel, and determine the result of comparing the output signal and the expected value information in parallel Output to
The test apparatus comprises:
A result of selecting the determination result from the edge strobe unit when the edge strobe mode is selected, and selecting the determination result from the multi-strobe unit when the multi-strobe mode is selected. A selection section;
The test apparatus according to claim 5, further comprising: a capture memory that stores the determination result selected by the result selection unit. The test apparatus according to claim 6, further comprising a result delay unit that delays the determination result output from the edge strobe unit and inputs the determination result to the result selection unit. The multi-strobe section is
A plurality of output signal side delay circuits that are cascaded and sequentially delay the output signal;
A plurality of strobe side delay circuits that are cascade-connected in a one-to-one correspondence with the plurality of output signal side delay circuits, and sequentially delay reference timing with a delay amount different from the corresponding output signal side delay circuits,
The strobe provided corresponding to the plurality of output signal side delay circuits and outputting the delayed output signal output from the corresponding output signal side delay circuit corresponding to the output signal side delay circuit. A plurality of acquisition units for acquiring at the reference timing delayed from the side delay circuit,
A timing generator for generating the reference timing and supplying the reference timing to the multi-strobe unit;
The test apparatus according to claim 5, further comprising: a timing adjustment delay circuit that delays the reference timing generated by the timing generation unit and supplies the delayed timing to the edge strobe unit. A multi-strobe unit that acquires the value of the output signal at a timing of a plurality of different strobes generated with reference to a designated reference timing;
When the multi-strobe mode is selected, the multi-strobe unit outputs a result of comparing the value acquired by the plurality of strobes at the reference timing with the expected value information, and the edge strobe mode is selected. A result selection unit that outputs a result of comparing the expected value information with a value corresponding to the predetermined strobe among the values acquired by the multi-strobe unit at each reference timing. The test apparatus according to claim 1, further comprising: The multi-strobe unit outputs a determination result obtained by comparing a value acquired by a plurality of the strobes and the expected value information for each reference timing,
The result selection unit selects and outputs the determination result corresponding to the predetermined strobe among the determination results received from the multi-strobe unit when the edge strobe mode is selected. Item 10. The test apparatus according to Item 9. The multi-strobe unit outputs a value acquired by a plurality of the strobes for each reference timing,
When the edge strobe mode is selected, the result selection unit compares the expected value information with a value corresponding to the predetermined strobe among the values received from the multi-strobe unit. The test apparatus according to claim 9, which outputs a result. A test method for testing a device under test,
Edge strobe mode for determining the quality of the output signal value of the device under test at the sequentially designated reference timing based on expected value information, and each reference timing generated based on each of the reference timings Having two operation modes of a multi-strobe mode for determining the quality of the value of the output signal in a plurality of strobes based on expected value information;
A test for converting a given expected value pattern into expected value information for edge strobe mode or expected value information for multi-strobe mode based on whether the edge strobe mode or the multi-strobe mode is selected Method. A manufacturing method for manufacturing an electronic device, comprising:
Forming the electronic device;
Testing the electronic device according to the test method of claim 12;
A method of manufacturing the electronic device by selecting a non-defective electronic device based on a test result of the electronic device and / or ranking according to electrical characteristics.

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