Coded data generation or conversion – Analog to or from digital conversion – Analog to digital conversion
Reexamination Certificate
2002-10-30
2003-12-16
JeanPierre, Peguy (Department: 2838)
Coded data generation or conversion
Analog to or from digital conversion
Analog to digital conversion
C341S163000, C341S161000
Reexamination Certificate
active
06664911
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to a differential input A/D converter which converts the potential difference between two analog input signals from an analog value to a digital value.
In a differential input A/D converter which converts the potential difference between two analog input signals from an analog value to a digital value, the potential difference between two analog input voltages needs to be converted into a digital value at the same time. In addition, in order to perform fine control by using a control device such as microcontroller on the basis of a converted digital value, conversion with higher accuracy is required.
The conventional differential input A/D converter shown in
FIG. 6
converts first and second analog input signals
1
and
2
into a single-end signal
7
by using an analog subtracter
101
. After the single-end signal
7
is sampled by a sample/hold circuit
102
, the sampled value is converted into a digital value by a successive approximation type A/D converter
103
. This signal is then output as a conversion result
6
. As shown in
FIG. 7
, the analog subtracter
101
is comprised of three operational amplifiers
111
to
113
and resistors
104
to
110
.
FIG. 8
shows another conventional differential input A/D converter. Referring to
FIG. 8
, the conventional differential input A/D converter converts a first analog input signal
1
into a digital value by using a first A/D converter
114
and outputs it as a first conversion result
11
. At the same time, the differential input A/D converter converts a second analog input signal
2
into a digital value by using a second A/D converter
115
and outputs it as a second conversion result
12
. The differential input A/D converter then calculates the difference between the first and second conversion results
11
and
12
by using a digital subtracter
116
, and outputs the difference as a differential conversion result
14
.
In the differential input A/D converter shown in
FIG. 6
, the three operational amplifiers
111
to
113
constituting the analog subtracter
101
have errors such as offsets. These errors are superimposed to become a conversion error, and hence the error in the differential input A/D converter increases. In addition, in order to prevent an increase in error due to the operational amplifiers
111
to
113
, the differential input A/D converter must incorporate high-precision operational amplifiers
111
to
113
. This however causes an increase in chip area.
In addition, only when the first analog input signal
1
higher in voltage than the second analog input signal
2
, the potential difference can be A/D-converted. If, however, the first analog input signal
1
is lower in voltage than the second analog input signal
2
, the conversion result becomes zero.
Letting ADCR1 be the value of the first conversion result
11
in the differential input A/D converter shown in
FIG. 8
, and ADCR2 be the value of the second conversion result
12
, a value ADCR of the differential conversion result
14
can be given by
ADCR=ADCR
1−
ADCR
2 (1)
In addition, letting Vin1 be the voltage of the first analog input signal
1
, Vin2 be the voltage of the second analog input signal
2
, Verr1 be the conversion error in the A/D converter
114
, Verr2 be the conversion error in the A/D converter
115
, V(ADCR1) be the function for which the first conversion result
11
is converted into an analog voltage, and V(ADCR2) be the function for which the second conversion result
12
is converted into an analog voltage, the voltages Vin1 and Vin2 are given by
Vin
1
=V
(
ADCR
1)+
Verr
1 (2)
Vin
2
=V
(
ADCR
2)+
Verr
2 (3)
Letting V(ADCR) be the function for which the differential conversion result
14
is converted into an analog voltage, the differential conversion result
14
obtained by the differential input A/D converter can be generally given by
Vin
1−
Vin
2
=V
(
ADCR
)+
Verr
(4)
Substitutions of equations (2) and (3) into equation (4) yield equation (5):
V
(
ADCR
)
+
Verr
=
{
V
(
ADCR1
)
+
Verr1
}
-
{
V
(
ADCR2
)
+
Verr2
}
=
V
(
ADCR1
)
-
V
(
ADCR2
)
+
Verr1
-
Verr2
(
5
)
The conversion error in the differential conversion result
14
therefore becomes (Verr1−Verr2). Since the conversion errors Verr1 and Verr2 are independent of each other, the error in the differential conversion result
14
is equal to the value obtained by superimposing the errors in the two A/D converters
114
and
115
. Therefore, in the differential input A/D converter shown in
FIG. 8
, if the errors in the two A/D converters
114
and
115
are similar, the conversion error becomes almost double, at maximum, that when one A/D converter is used.
With regard to quantization errors which A/D converters theoretically have, in particular, a quantization error of −½ to +½ LSB in the A/D converter
114
and a quantization error of −½ to +½ LSB in the A/D converter
115
are added together. As a consequence, the differential input A/D converter has a quantization error of −1.0 to +1.0 LSB. In other words, if the resolution of the two A/D converters
114
and
115
is n bits, the resolution of the differential input A/D converter constituted by the A/D converter
114
and
115
becomes substantially (n−1) bits, which is smaller than n bits by one bit.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a high-precision differential input A/D converter without increasing the precision of A/D converters and analog subtracters.
In order to achieve the above object, according to the present invention, there is provided a differential input A/D converter which converts a potential difference between two analog input signals from an analog value to a digital value, comprising first A/D conversion means for outputting a first conversion result obtained by A/D-converting a first analog input signal, second A/D conversion means for outputting a second conversion result obtained by A/D-converting a second analog input signal, and digital subtraction means for outputting a differential conversion result obtained by subtracting the second conversion result output from the second A/D conversion means from the first conversion result output from the first A/D conversion means, wherein the first A/D conversion means A/D-converts a difference between an analog value obtained from an output of the second A/D conversion means and the second analog input signal output from the second A/D conversion means and superimposes the A/D conversion result on the first conversion result.
REFERENCES:
patent: 5072220 (1991-12-01), Petschacher et al.
patent: 5764175 (1998-06-01), Pan
patent: 6411241 (2002-06-01), Taketoshi
patent: 6424284 (2002-07-01), Lopata et al.
patent: 2002/0154049 (2002-10-01), Hsueh
Jean-Pierre Peguy
McGinn & Gibb PLLC
NEC Electronics Corporation
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