Electricity: measuring and testing – Fault detecting in electric circuits and of electric components – Of individual circuit component or element
Reexamination Certificate
1999-09-10
2001-09-04
Karlsen, Ernest (Department: 2858)
Electricity: measuring and testing
Fault detecting in electric circuits and of electric components
Of individual circuit component or element
C324S1540PB, C327S341000, C327S362000
Reexamination Certificate
active
06285206
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a comparator circuit suitable for use in, for example, a semiconductor integrated circuit testing apparatus for testing and measuring various types of semiconductor integrated circuits.
2. Description of the Related Art
In a semiconductor integrated circuit testing apparatus (hereinafter referred to as IC testing apparatus) for testing and measuring a semiconductor integrated circuit (hereinafter referred to as IC), by way of example, if an IC to be tested (IC under test) is a digital type IC directed to a digital signal processing, whether or not the voltage of a response signal outputted from this IC under test has a prescribed voltage value of logical H (logical high level) or a prescribed voltage value of logical L (logical low level) is determined by a comparator circuit. Specifically, the comparator circuit determines whether the voltage of logical H outputted from the IC under test has a voltage value equal to or higher than the prescribed voltage value or not, or the comparator circuit determines whether the voltage of logical L outputted from the IC under test has a voltage value equal to or lower than the prescribed voltage value or not. When the determination result is “pass” (the response signal has a prescribed voltage value), the comparator circuit outputs a signal of logical H or logical L indicating “the pass result”, and this logical signal is sent to a logical comparator circuit for inspecting whether the response of the IC under test is correct or not.
FIG. 4
shows an example of the comparator circuit of this type used in a conventional IC testing apparatus. Although only one voltage comparator VCP used in the comparator circuit is shown in
FIG. 4
, in a practically used IC testing apparatus both the voltage of logical H and the voltage of logical L are compared and determined in the comparator circuit as to whether they have the prescribed voltages, respectively, and hence two voltage comparators are used in the comparator circuit. Here, since the comparisons of the two voltage values are not the requirements of the present invention, only one voltage comparator VCP for performing a voltage comparison for logical H is illustrated for clarity of the explanation, and the operation thereof will be described.
The voltage comparator VCP has, in this example, two input terminals one of which is a non-inverting input terminal and the other of which is an inverting input terminal, and an output terminal. The inverting input terminal is connected to a comparison (reference) voltage source
16
for outputting a prescribed comparison (reference) voltage V
REF
.
In a readout mode in which a test pattern signal already written in an IC under test
10
is read out therefrom, as the IC under test is viewed from the outside, it can be considered to have a voltage output source
11
therein. Assuming that the voltage output source
11
outputs a voltage V
O
, this voltage V
O
is supplied to one input terminal (in this example, the non-inverting input terminal) of the voltage comparator VCP via a signal line
12
from one terminal to which the voltage output source
11
is connected. Herein, the voltage V
O
outputted from the voltage output source
11
will be referred to as an input voltage to the voltage comparator VCP. The voltage comparator VCP functions, in this example, as a subtracter for subtracting the comparison voltage V
REF
from an input voltage applied to the non-inverting input terminal thereof and outputting a voltage of logical H or a voltage of logical L.
The signal line
12
for electrically connecting between the IC under test
10
and the one input terminal of the voltage comparator VCP has a resistance component. A total resistance component that exists in the input circuit for the voltage comparator VCP including this resistance component in the signal line
12
and a resistance component in a switch (not shown) for disconnecting the voltage comparator VCP from the IC under test
10
is denoted by a reference character
13
, and its resistance value is represented by RON. In a write mode in which a test pattern signal is written in the IC under test
10
, a driver (not shown) is connected to the IC under test
10
, and the voltage comparator VCP is disconnected from the IC under test
10
. The above switch is one for disconnecting the voltage comparator VCP from the IC under test
10
in the write mode, and a relay or a semiconductor switch element is usually used as such switch.
In order to take an impedance matching on the signal line
12
, a terminating resistor (terminator)
14
is connected to the signal line
12
, and further a terminator voltage source
15
for the terminating resistor
14
is provided. For example, in the case that the signal line
12
has its characteristic impedance of 50 &OHgr;, the resistance value of the terminating resistor
14
is also set to 50 &OHgr;, theby to terminate the terminal end of the signal line
12
with 50 &OHgr; to maintain the signal line in the state that no reflection occurs.
Assuming that an output voltage of the terminator voltage source
15
is VTT, the resistance value of the terminating resistor
14
is RT and a connection point or junction between the terminating resistor
14
and the resistance component
13
that exists in the input circuit for the voltage comparator VCP is A, an electric potential at the connection point A is applied to the one input terminal of the voltage comparator VCP since the connection point A is connected to the one input terminal of the voltage comparator VCP. The electric potential of the connection point A is divided in voltage by a voltage dividing resistance circuit composed of the resistance value RON of the resistance component
13
and the resistance value RT of the terminating resistor
14
. Accordingly, assuming that the divided voltage is V
O
′, this divided voltage V
O
′ is supplied to the one input terminal of the voltage comparator VCP.
The output voltage VTT of the terminator voltage source
15
is set to just the middle voltage between a voltage VH of logical H and a voltage VL of logical L outputted from the voltage output source
11
of the IC under test
10
(½ of the voltage of (VH+VL)). Due to such terminator voltage VTT, the electric potential at the connection point A is maintained at the voltage VTT when the output terminal of the IC under test
10
becomes high impedance mode. As a result, even if the IC under test
10
outputs a voltage of logical H or a voltage of logical L after that, a change in electric potential at the junction A is limited to half (½) of the voltage (VH−VL). Accordingly, the provision of the terminator voltage source
15
results in that the electric potential at the junction A can reach the target voltage value at high speed. For this reason, the terminator voltage source
15
is usually connected to the terminating resistor
14
.
When the voltage V
O
′ at the connection point A is inputted to the one input terminal (in this example, non-inverting input terminal) of the voltage comparator VCP, and the comparison voltage V
REF
outputted from the comparison voltage source
16
is inputted to the other input terminal (in this example, inverting input terminal) of the voltage comparator VCP, the voltage V
O
′ being a divided voltage of the input voltage V
O
outputted from the IC under test
10
, the voltage comparator VCP outputs a voltage of logical H as shown in
FIG. 6B
if the voltage V
O
′ of the connection point A is higher than the comparison voltage V
REF
(V
O
′>V
REF
), and outputs a voltage of logical L if the voltage V
O
′ of the connection point A is lower than the comparison voltage V
REF
(V
O
′<V
REF
).
As mentioned above, in the comparator circuit in the IC testing apparatus, since the IC under test
10
is connected to the one input terminal of the voltage comparator VCP by the signal line
12
, there is a drawback that the operation of
Advantest Corporation
Gallagher & Lathrop
Karlsen Ernest
Lathrop David N.
Tang Minh
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