Electricity: measuring and testing – Impedance – admittance or other quantities representative of... – With auxiliary means to condition stimulus/response signals
Reexamination Certificate
2000-06-16
2002-07-02
Le, N. (Department: 2858)
Electricity: measuring and testing
Impedance, admittance or other quantities representative of...
With auxiliary means to condition stimulus/response signals
Reexamination Certificate
active
06414496
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to automatic test equipment (ATE) and, more particularly, to measurement errors in ATEs.
2. Description of the Related Art
Exemplary automatic test equipments (ATEs) are typically configured to quickly test the responses of a large number of electronic modules which are conventionally referred to as devices under test (DUTs). In general, each DUT has been designed to receive input stimulation signals S
in
at a first set of DUT terminals and, in response, generate output signals S
out
at a second set of terminals. Accordingly, an exemplary ATE generates the input signals, applies them to the first terminal set of each DUT and receives and analyzes the output signals S
out
from the second terminal set of each DUT to determine which DUTs meet their specified performance. Because this performance must generally be met while supplying or sinking a specified current, the exemplary ATE also applies a specified current load to the DUT.
ATEs typically include a large number of test interface modules that are each coupled to a terminal of a respective one of the DUTs. Each test interface module generally incudes circuits that a) generate input driving signals for its respective DUT, b) compare the DUT's output signals to reference signals and c) apply specified current loads to the DUT. Because these test interface circuits realize driving, comparing and loading functions, they are typically called DCL modules (D, C and L respectively referring to the driving, comparing and loading functions). In addition, the driver circuits are often referred to as “pin drivers” because they apply input signals to DUT terminals or pins.
The output signals S
out
are carried along transmission channels or paths from the DUTs to the ATE comparators that characterize or analyze them by comparing them to reference signals S
ref
. Unfortunately, all transmission paths have transmission parameters (e.g., skin effect and dielectric absorption) that induce signal distortion so that output signals S
out
enter the transmission paths but distorted output signals S
dstrd-out
exit the paths. The reference signals S
ref
are therefore compared to distorted output signals S
dstrd-out
rather than to the original output signals S
out
. Therefore, the ATEs performance measurement is in error because it is incorrectly based upon the distorted output signals S
dstrd-out
.
For example,
FIG. 1
shows a DUT
20
and a plurality of test interface modules
22
A,
22
B-
22
N that are each coupled to a respective one of of the DUT's terminals
24
. The test interface module
22
A is detailed to show that it includes a driver in the form of a waveform synthesizer
26
, a comparator
28
and an active load
30
. In response to control signals S
cntrl
32
, the synthesizer and the active load can apply specified input driving signals and current loads to the terminal
32
of the DUT
20
. The other test interface modules can provide similar measurement functions to their respective DUT terminals.
The DUT
20
generates an output signal S
out
at the terminal
34
and it is carried over a transmission path
36
to the comparator
28
which compares this signal to a reference signal S
ref
and delivers a resultant output at an output port P
out
. Although the transmission path
36
is indicated as a coaxial cable, it can take on other transmission path forms, (e.g., wires, striplines and microstrips). Regardless of its exact form, the transmission path
34
will impose a signal distortion upon the output signal S
out
. A distorted signal is thus presented to the comparator
28
and, accordingly, its output at the output port P
out
characterizes this distorted signal rather than the output signal S
out
.
FIG. 2A
shows an exemplary output signal S
out
40
that is provided to the comparator
28
over a transmission path
36
that imposes a signal distortion so that a distorted output signal S
dst-out
42
is received by the comparator
28
. With the aid of a level-shifted reference signal S
ref
, the comparator
28
can detect amplitudes of the distorted output signal at respective test times T
tst
throughout the signal's duration.
For example, at an exemplary test time
44
of
FIG. 2A
, a latch signal can be applied to the comparator
28
to thereby latch its output at the output port P
out
. By observing the latched output for each of a plurality of level-shifted reference signals S
ref
, a reference signal level
46
can be found wherein above this signal level, the comparator's output has one polarity and below it, the comparator's output has an opposite polarity. Thus, the distorted output signal
42
has an amplitude substantially equal to the reference signal level
46
at the exemplary test time
44
. This process can be automated with various conventional circuits. An integrator
48
, for example, will automatically servo the reference signal to the final reference value
46
.
FIG. 2B
repeats the distorted output signal
42
and shows a table
50
of corresponding time and voltage pairs wherein each voltage V
tst
is the amplitude of the distorted output signal at a test time that is determined by a respective latch delay D
latch
. In this exemplary process (sometimes referred to as “digitizing” or, in ATE vernacular, “schmooing”), the comparator
28
of
FIGS. 1 and 2A
can determine time and voltage pairs that define the shape and timing of a signal at its input. Because this signal is, however, the distorted output signal
42
of
FIG. 2A
, the table
50
of
FIG. 2B
includes measurement errors generated by the signal distortion of the transmission path
36
.
Numerous efforts (e.g., see U.S. Pat. No. 5,216,373, 5,532,590, 5,940,441, 5,955,890 and 6,016,566) have been directed to the correction and/or compensation of ATE measurement errors that originate because of transmission-path signal distortion. Although these efforts may reduce the distortion-induced errors, they are generally complex solutions that would impose unacceptable cost increases in ATEs that are configured to simultaneously test large numbers (e.g., hundreds) of DUTs.
SUMMARY OF THE INVENTION
The present invention is directed to comparator methods and structures whose accuracy in analyzing an output signal S
out
of a DUT is enhanced because they compensate for a signal distortion that is imposed by a transmission path over which the output signal S
out
is received.
These goals are realized with an analysis method that comprises the process steps of:
a) providing a reference signal S
ref
,
b) combining the reference signal S
ref
with a reference distortion that corresponds to the signal distortion to thereby realize a compensated reference signal S
cmp-ref
, and
c) comparing the output signal S
out
to the compensated reference signal S
cmp-ref
to determine signal parameters of the output signal S
out
.
In a method embodiment, the providing step includes the step of configuring the reference signal S
ref
as a constant reference voltage V
ref
that can be level-shifted and the combining step includes the step of configuring a first time portion of the compensated reference signal S
cmp-ref
to substantially equal the reference voltage V
ref
and a second time portion of the compensated reference signal S
cmp-ref
to substantially track the signal distortion.
In another method embodiment, the comparing step includes the step of level-shifting the reference signal S
ref
, at each of test times T
tst
, to determine a reference signal level L
ref
for which the compensated reference signal S
cmp-ref
substantially equals the output signal S
out
at that test time T
tst
.
The methods of the invention facilitate the use of simple comparator structures that do not significantly increase the cost of ATEs but which do significantly increase accuracy of signal analysis.
The novel features of the invention are set forth with particularity in the appended claims. The invention will be best understood from the following description whe
Analog Devices Inc.
Koppel, Jacobs Patrick & Heybl
Le N.
LeRoux Etienne P
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