TEST APPARATUS, INFORMATION PROCESSING SYSTEM AND DATA TRANSFER METHOD

Abstract

Provided is a test apparatus that tests a device under test, comprising a test unit that sends and receives signals to and from the device under test; a control apparatus that controls the test unit; and a relay apparatus that relays between the control apparatus and the test unit. The relay apparatus includes a read issuing section that receives a command from the control apparatus and issues a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the test unit; a buffer section that buffers the read data transmitted from the test unit in response to the read command; and a data transmitting section that receives the read command from the control apparatus and sends back the read data buffered in the buffer section.

Description

BACKGROUND

1. Technical Field

The present invention relates to a test apparatus, an information processing system, and a data transfer method for testing a device under test.

2. Related Art

A test apparatus for testing a semiconductor device or the like includes one or more test units and a control apparatus. Each test unit supplies a test signal to the device under test.

The control apparatus can be realized as a computer connected to the test units via a serial communication cable or the like. The control apparatus issues commands to each of the test units to control the test units.

For example, when reading data such as test results from a storage apparatus in a test unit, the control apparatus issues a read command to the test unit and receives a response to the read command. After a read command has been issued to the test unit, the control apparatus must be in a standby state not performing other processes until receiving the response to the read command.

In recent test apparatuses, however, the test units supplying test signals to the devices under test are controlled from remote control apparatuses. As a result, the total time from when a control apparatus issues a read command to when the response is received is increased, thereby increasing the processing time of the control apparatus.

SUMMARY

Therefore, it is an object of an aspect of the innovations herein to provide a test apparatus, an information processing system, and a data transfer method, which are capable of overcoming the above drawbacks accompanying the related art. The above and other objects can be achieved by combinations described in the independent claims. The dependent claims define further advantageous and exemplary combinations of the innovations herein.

According to a first aspect related to the innovations herein, provided is a test apparatus that tests a device under test, comprising a test unit that sends and receives signals to and from the device under test; a control apparatus that controls the test unit; and a relay apparatus that relays between the control apparatus and the test unit. The relay apparatus includes a read issuing section that receives a command from the control apparatus and issues a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the test unit; a buffer section that buffers the read data transmitted from the test unit in response to the read command; and a data transmitting section that receives the read command from the control apparatus and sends back the read data buffered in the buffer section.

According to a second aspect related to the innovations herein, provided is an information processing system comprising a processing unit; a control apparatus that controls the processing unit; and a relay apparatus that relays between the control apparatus and the processing unit. The relay apparatus includes a read issuing section that receives a command from the control apparatus and issues a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the processing unit; a buffer section that buffers the read data transmitted from the processing unit in response to the read command; and a data transmitting section that receives the read command from the control apparatus and sends back the read data buffered in the buffer section.

According to a third aspect related to the innovations herein, provided is a data transfer method performed by a test apparatus that tests a device under test, wherein the test apparatus includes a test unit that sends and receives signals to and from the device under test; a control apparatus that controls the test unit; and a relay apparatus that relays between the control apparatus and the test unit. The data transfer method comprises receiving a command from the control apparatus and issuing a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the test unit, by a read issuing section of the relay apparatus; buffering the read data transmitted from the test unit in response to the read command, by a buffer section of the relay apparatus; and receiving the read command from the control apparatus and sending back the read data buffered in the buffer section, by a data transmitting section of the relay apparatus.

The summary clause does not necessarily describe all necessary features of the embodiments of the present invention. The present invention may also be a sub-combination of the features described above. The above and other features and advantages of the present invention will become more apparent from the following description of the embodiments taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a configuration of a test apparatus 10 according to an embodiment of the present invention.

FIG. 2 shows configurations of a test unit 12 and the relay apparatus 16 according to the present embodiment.

FIG. 3 shows exemplary propagation of a normal read command issued to the test unit 12 by the control apparatus 14.

FIG. 4 shows exemplary propagation of commands when the control apparatus 14 issues commands that are different from the normal commands of FIG. 3, to read data from the test unit 12.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, some embodiments of the present invention will be described. The embodiments do not limit the invention according to the claims, and all the combinations of the features described in the embodiments are not necessarily essential to means provided by aspects of the invention.

FIG. 1 shows a configuration of a test apparatus 10 according to an embodiment of the present invention. The test apparatus 10 tests a device under test such as a semiconductor device. The test apparatus 10 includes one or more test units 12, a control apparatus 14, and a relay apparatus 16.

Each test unit 12 sends and receives signals to and from the device under test. For example, each test unit 12 may supply the device under test with a test signal having a waveform corresponding to a test pattern, and judge acceptability of the device under test by comparing a response signal from the device under test to a logic value corresponding to an expected value pattern.

The control apparatus 14 provides a command to each of the one or more test units 12 to control the test units 12. The control apparatus 14 may be realized as a computer that functions as the control apparatus 14 by executing a program.

The relay apparatus 16 relays commands and responses between the control apparatus 14 and the one or more test units 12. For example, one or more transmission lines 22, which each have a length of several meters, may be connected between the control apparatus 14 and one or more relay apparatuses 16 to transmit serial data. A tester bus 24 may be connected between the relay apparatus 16 and the test units 12 to transmit parallel data.

FIG. 2 shows configurations of a test unit 12 and the relay apparatus 16 according to the present embodiment. The relay apparatus 16 includes a register 26, a read issuing section 28, a first communicating section 30, a second communicating section 32, a buffer section 34, a data transmitting section 36, and a bus IF section 38.

Data is written to the register 26 according to commands from the control apparatus 14. In the present embodiment, data designating an address in a storage apparatus of a test unit 12 is written to the register 26.

The read issuing section 28 receives a command from the control apparatus 14 and issues a read command for reading read data stored in the storage apparatus of the test unit 12 at an address designated by the control apparatus 14. In the present embodiment, the read issuing section 28 issues the read command for reading the read data stored at the address indicated by data written in the register 26, in response to data being written in the register 26.

The first communicating section 30 receives from the control apparatus 14 commands transmitted from the control apparatus 14 to the test unit 12. The first communicating section 30 receives the read command issued from the read issuing section 28. The first communicating section 30 generates packets including the received commands. The first communicating section 30 transmits each of the generated packets to the transmission line 22 connected to the test unit 12 that is the transmission destination for the packet, via the bus IF section 38.

The second communicating section 32 receives, via the bus IF section 38, packets transmitted from the one or more test units 12. The second communicating section 32 extracts commands or responses to commands transmitted thereto included in the packets. The second communicating section 32 transmits to the control apparatus 14 the extracted commands or responses. After acquiring the read data, which is the response sent from the test unit 12 in response to the read command issued by the read issuing section 28, the second communicating section 32 writes the read data to the buffer section 34 instead of transmitting the read data to the control apparatus 14.

The buffer section 34 buffers the read data written by the second communicating section 32. The data transmitting section 36 receives the read command from the control apparatus 14 and sends back the read data buffered in the buffer section 34.

The relay apparatus 16 may include a plurality of buffer sections 34 corresponding to each of a plurality of test units 12. In this case, the buffer sections 34 each buffer the read data transmitted from the corresponding test unit 12. Furthermore, in this case, the data transmitting section 36 reads the read data from the buffer section 34 corresponding to the test unit 12 designated by the read command, and transmits this read data to the control apparatus 14.

The bus IF section 38 converts the data transmitted from the relay apparatus 16 to the test unit 12, from a format such as parallel data that can be handled by the relay apparatus 16 to a format such as serial data that can be transmitted on the transmission line 22. The bus IF section 38 also converts data sent from the test unit 12 to the relay apparatus 16, from a format such as serial data that can be transmitted on the transmission line 22 to a format such as parallel data that can be handled by the relay apparatus 16.

The one or more test units 12 each include a functional testing section 42, a DC testing section 44, a bus IF section 46, and a sending/receiving section 48. The functional testing section 42 performs functional testing on the device under test. The functional testing section 42 operates according to a command received from the control apparatus 14.

The DC testing section 44 supplies DC power supply voltage to the device under test. The DC testing section 44 performs DC testing on the device under test. The DC testing section 44 operates according to a command from the control apparatus 14.

The bus IF section 46 converts the data transmitted from the test unit 12 to the relay apparatus 16, from a format such as parallel data that can be handled by the test unit 12 to a format such as serial data that can be transmitted on the transmission line 22. The bus IF section 46 converts the data transmitted from the relay apparatus 16 to the test unit 12, from a format such as serial data that can be transmitted on the transmission line 22 to a format such as parallel data that can be handled by the test unit 12.

The sending/receiving section 48 receives, from the relay apparatus 16 via the bus IF section 46, packets including commands or responses sent from the control apparatus 14 to the test unit 12. The sending/receiving section 48 extracts the commands or responses included in the packets. The sending/receiving section 48 transmits the extracted commands or responses to the functional testing section 42 or the DC testing section 44.

The sending/receiving section 48 receives commands or responses to be transmitted from the functional testing section 42 and the DC testing section 44 to the control apparatus 14. The sending/receiving section 48 generates packets including the received commands or responses. The sending/receiving section 48 transmits the generated packets to the relay apparatus 16 via the bus IF section 46.

FIG. 3 shows exemplary propagation of a normal read command issued to the test unit 12 by the control apparatus 14. In FIG. 3, commands beginning with “srd” represent read commands for reading data from a designated address in a storage apparatus. The term “TH1 PG” following the “srd” in the read commands represents an address designating the location to read the data from. In FIG. 3, commands including “DATA” following “srd TH1 PG” represent responses corresponding to the read commands. FIG. 4 uses the same labeling.

The read command shown in FIG. 3 is issued by the control apparatus 14. The read command issued by the control apparatus 14 is sequentially transmitted in the following order: control apparatus 14→relay apparatus 16→sending/receiving section 48 of the test unit 12→functional testing section 42 of the test unit 12. Upon receiving the read command, the functional testing section 42 of the test unit 12 reads the data from the address indicated by the read command, and issues a response that contains the read data. The response issued by the functional testing section 42 of the test unit 12 is sequentially transmitted in the following order: functional testing section 42 of the test unit 12→sending/receiving section 48 of the test unit 12→relay apparatus 16→control apparatus 14.

Upon issuing the read command, the control apparatus 14 cannot perform a subsequent process until the response to the read command is received. Accordingly, in the present example, the control apparatus 14 cannot perform processes from time 2 to time 12.

FIG. 4 shows exemplary propagation of commands when the control apparatus 14 issues commands that are different from the normal commands of FIG. 3, to read data from the test unit 12. The control apparatus 14 of the present embodiment issues commands to the relay apparatus 16 that differ from the normal read command shown in FIG. 3, reads the data from the test unit 12, and temporarily holds the data in the relay apparatus 16. In the present embodiment, this process is referred to as “posted read.”

In FIG. 4, the commands having “swt PRD” at the beginning thereof represent write commands that are issued to the relay apparatus 16 by the control apparatus 14 and that instruct the relay apparatus 16 to perform the posted read. The term “TH1 PG(X)” following the “swt PRD” represents an address designating the location from which data is read according to the posted read.

In FIG. 4, commands including “srd TP Buf” represent read commands for reading data temporarily held by the relay apparatus 16 according to the posted read. In FIG. 4, the command included in “DATA” following “srd TP Buf” represents a response corresponding to the read command.

When the relay apparatus 16 is to perform the posted read, the control apparatus 14 issues a write command to the relay apparatus 16. In this case, the control apparatus 14 writes data designating an address in a storage apparatus of a test unit 12 to the register 26.

The read issuing section 28 of the relay apparatus 16 generates a normal read command for reading the read data stored at the address indicated by data written in the register 26, and is triggered by data being written in the register 26. The first communicating section 30 of the relay apparatus 16 then generates a packet including the read command generated by the read issuing section 28, and transmits the packet to the corresponding test unit 12.

The sending/receiving section 48 of the test unit 12 receives the read command from the relay apparatus 16. The sending/receiving section 48 of the test unit 12 supplies the corresponding processing section, i.e. the functional testing section 42 or the DC testing section 44, with the received read command. The processing section that receives the read command transmits the data stored at the address in the storage apparatus designated by the read command to the sending/receiving section 48, as read data. Upon receiving the read data, the sending/receiving section 48 of the test unit 12 generates a packet including the read data and transmits the packet back to the relay apparatus 16.

Next, the second communicating section 32 of the relay apparatus 16 receives the packet including the read data from the test unit 12. The second communicating section 32 of the relay apparatus 16 extracts the read data from the received packet and writes the read data to the buffer section 34. In this way, the relay apparatus 16 can read data from the test unit 12 and temporarily hold this data.

When reading the read data temporarily held according to the posted read, the control apparatus 14 issues a read command to the relay apparatus 16. The data transmitting section 36 of the relay apparatus 16 receives the read command from the control apparatus 14 and sends the read data buffered in the buffer section 34 back to the control apparatus 14.

The data transmitting section 36 may receive a confirmation command from the control apparatus 14 and send back status information indicating the buffering status of the read data by the buffer section 34. For example, the data transmitting section 36 may transmit, as the status information, a flag indicating whether the buffer section 34 is buffering the read data or the number of pieces of read data buffered in the buffer section 34. As a result, the control apparatus 14 can issue read commands to the relay apparatus 16 after confirming that the buffer section 34 is buffering the read data.

When a read command is received from the control apparatus 14 while the buffer section 34 is not buffering the read data, the data transmitting section 36 may postpone completion of the read command until the read data is buffered in the buffer section 34. In other words, when the buffer section 34 is not buffering read data, the data transmitting section 36 may postpone the transmission of data in response to the read command received from the control apparatus 14. As a result, when a read command is received from the control apparatus 14, the data transmitting section 36 can reliably send the read data back to the control apparatus 14.

In this way, the control apparatus 14 can read data in a storage apparatus of a test unit 12 without issuing a read command to the test unit 12. Furthermore, unlike a case in which a read command is issued, the control apparatus 14 can perform a subsequent process immediately after issuing the write command. Accordingly, in the example of FIG. 4, the control apparatus 14 can perform other processes from time 5 onward. As a result, the test apparatus 10 can efficiently read data from the test unit 12 without having a wait time for the reading of data by the control apparatus 14.

The control apparatus 14 may instruct the relay apparatus 16 to perform the posted read by using a read command instead of the write command. In this case, the control apparatus 14 issues a read command for reading data from the register 26. The read issuing section 28 may issue a normal read command for reading data from an address in the storage apparatus of a test unit 12, with the reading of data from the register 26 as a trigger.

While the embodiments of the present invention have been described, the technical scope of the invention is not limited to the above described embodiments. It is apparent to persons skilled in the art that various alterations and improvements can be added to the above-described embodiments. It is also apparent from the scope of the claims that the embodiments added with such alterations or improvements can be included in the technical scope of the invention.

The technology described via the above embodiments is not limited to use in a test apparatus 10, and can be applied in a common information processing system. For example, the technology described via the above embodiments can be applied in an information processing system that includes one or more processing units that process information, a control apparatus that controls the processing units, and a relay apparatus that relays between the control apparatus and the processing units. In this case, the processing units of the information processing system have the same function and configuration as the test units 12 according to the above embodiments, the control apparatus of the information processing system has the same function and configuration as the control apparatus 14 according to the above embodiments, and the relay apparatus of the information processing system has the same function and configuration as the relay apparatus 16 according to the above embodiments.

Claims

1. A test apparatus that tests a device under test, comprising:

a test unit that sends and receives signals to and from the device under test;

a control apparatus that controls the test unit; and

a relay apparatus that relays between the control apparatus and the test unit, wherein the relay apparatus includes:

a read issuing section that receives a command from the control apparatus and issues a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the test unit;

a buffer section that buffers the read data transmitted from the test unit in response to the read command; and

a data transmitting section that receives the read command from the control apparatus and sends back the read data buffered in the buffer section.

2. The test apparatus according to claim 1, wherein

the relay apparatus further includes a register in which data is written according to the command from the control apparatus, and

the read issuing section issues the read command in response to data being written to the register.

3. The test apparatus according to claim 2, wherein

the control apparatus writes, to the register, data designating an address in the storage apparatus of the test unit, and

the read issuing section issues the read command for reading the read data stored at the address indicated by the data written in the register.

4. The test apparatus according to claim 1, wherein

in the relay apparatus, the data transmitting section receives a confirmation command from the control apparatus and sends back status information indicating buffering status of the read data in the buffer section.

5. The test apparatus according to claim 1, wherein

when the read command is received from the control apparatus while read data is not being buffered in the buffer section, the data transmitting section postpones completion of the read command until the read data is buffered in the buffer section.

6. The test apparatus according to claim 1, comprising a plurality of the test units, wherein

the relay apparatus includes a plurality of the buffer sections corresponding respectively to the test units, each buffer section buffering the read data transmitted thereto by the corresponding test unit.

7. An information processing system comprising:

a processing unit;

a control apparatus that controls the processing unit; and

a relay apparatus that relays between the control apparatus and the processing unit, wherein the relay apparatus includes:

a read issuing section that receives a command from the control apparatus and issues a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the processing unit;

a buffer section that buffers the read data transmitted from the processing unit in response to the read command; and

a data transmitting section that receives the read command from the control apparatus and sends back the read data buffered in the buffer section.

8. A data transfer method performed by a test apparatus that tests a device under test, wherein the test apparatus includes:

a test unit that sends and receives signals to and from the device under test;

a control apparatus that controls the test unit; and

a relay apparatus that relays between the control apparatus and the test unit, the data transfer method comprising:

receiving a command from the control apparatus and issuing a read command for reading read data stored at an address designated by the control apparatus in a storage apparatus of the test unit, by a read issuing section of the relay apparatus;

buffering the read data transmitted from the test unit in response to the read command, by a buffer section of the relay apparatus; and

receiving the read command from the control apparatus and sending back the read data buffered in the buffer section, by a data transmitting section of the relay apparatus.