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Claims  |
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What is claimed is:
1. An input circuit for connection to an analog-to-digital converter,
comprising:
computer means for controlling operation of the input circuit;
an integrator that further comprises first amplifier means and a capacitor
means connected between an input and output of the first amplifier in a
feedback connection, the input to the integrator being the input of the
first amplifier means and the output of the integrator being the output of
the first amplifier means, with the input to the integrator being a summed
signal including a measuring signal and a signal output from a
digital-to-analog converter;
a programmable amplifier that has an input that connects to the output of
the integrator and an output that connects to the input of an
analog-to-digital converter, the analog-to-digital converter having an
output that connects to an input to the computer means, the programmable
amplifier for programmably amplifying signals input thereto from the
integrator;
digital-to-analog converter that has an input that connects to an output of
the computer means and the output connects to the input of the integrator,
the digital-to-analog converter for converting signals output from the
computer means that control integrator operations so the output of the
integrator remains in a non-saturated region; and
resistor means connected between the output of the digital-to-analog
converter and the input to the integrator, the resistor means having a
predetermined relationship with the capacitor means for integrating the
summed signal input to the integrator.
2. The input circuit recited in claim 1, wherein the digital-to-analog
converter comprises means for emitting pulse-width modulated signals, the
pulse-width modulated signal being coupled to the integrator.
3. The input circuit recited in claim 1, wherein the programmable amplifier
is controlled by the computer means.
4. The input circuit recited in claim 1, wherein the analog-to-digital
converter is integral with the computer means.
5. The input circuit recited in claim 1, wherein the first amplifier
includes a preamplifier.
6. The input circuit recited in claim 1, wherein the computer means is
connected to several input circuits operating in parallel.
7. The input circuit recited in claim 1, wherein the first amplifier
comprises a single stage amplifier.
8. The input circuit recited in claim 1, wherein the first amplifier
comprises a multi-stage amplifier.
9. The input circuit recited in claim 1, wherein the computer means
comprises a microprocessor or microcomputer. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
Modern data acquisition systems employ analog digital converters of
essentially three types: Converters with very short conversion times,
so-called half-flash converters; converters which operate according to the
successive approximation (SAR) method, where the input voltage is compared
to the output voltage of a digital-analog converter, which is controlled
by the SAR register; and integrating converters, which are applied
wherever short conversion times are not required. In the case of the
so-called half-flash converter, the internal resistance must be small in
order to keep error to a minimum. With regard to their input voltage, the
SAR converters are very sensitive. As far as internal resistance is
concerned, the most insensitive of all three types of converters in any
case is the integrating converter. However, with this type of converter,
one must be aware of the fact that the input current is essentially a
leakage current and that when several integration levels are involved, the
errors add up.
SUMMARY OF THE INVENTION
An object of the invention is to provide a configuration for analog to
digital conversion of the third type, and which, in particular, in spite
of low circuit expenditure and greater conversion speed, avoids
quantization errors.
The above and other objects of the present invention are achieved by an
apparatus for converting analog signals into digital signals with a single
or multi-stage amplifier, which forms the input circuit of an
analog-digital converter, whose digital output data are fed to a
microprocessor or microcomputer, at least one amplifier of the input
circuit comprising an integrator with capacitance included in a feedback
path, wherein the difference between the analog measuring signal and a
further signal controlled by the microprocessor or microcomputer by means
of digital-analog conversion is applied to the input of the integrator,
the integrator being controlled through the signal feedback without being
reset, so that the integrator never becomes saturated, and the digital
value acquired within one measuring interval being formed from the sum of
the value of the digital-analog converter and of the change in the
integrator signal detected by the analog-digital converter.
Important advantages of the invention are: reduced or no quantization
errors, higher resolution, less noise, greater speed and a lesser degree
of complexity.
With the invention, a rapidly changing analog voltage, upon which noise and
interfering signals are superimposed, is capable of being scanned within a
fixed time reference and digitized, whereby the instantaneous value of the
applied voltage is detected with the greatest possible accuracy.
Furthermore, with the invention, the integration can be made from the
digital values over long periods of time with minimal errors. The sampling
rate between two sampling instants is no longer of importance for the
integration, nor is the limited bit number of the analog-digital
converter, which, in the current state of technological development, can
lead to digitization errors. Both kinds of errors can lead to an
integrated signal error which becomes greater with time. The invention
avoids these errors with a level of complexity which is amazingly low.
BRIEF DESCRIPTION OF THE DRAWING
An exemplified embodiment of the invention is depicted schematically in the
single drawing FIGURE.
DETAILED DESCRIPTION
With reference now to the drawing, in the converter according to the
invention, in the area of the input circuit for a microprocessor or
microcomputer, as the FIGURE shows, the analog measuring signal 21 is
integrated in the analog preamplifier 22, together with a signal 23 of a
digital-analog converter 24 preamplifier 22 may be a single or multi-stage
amplifier. At this point, the analog integrating signal 25 is digitized by
an analog-digital converter 26, on which no special demands have to be
made, especially not concerning the bit number, and fed to the
microprocessor or microcomputer 27. It is advantageous when the
analog-digital converter 26 is integrated into microprocessor or
microcomputer 27.
For special requirements in the dynamic operating range (according to the
selection of R and C, the product of the resolution of the analog-digital
converter and of the resolution of the digital-analog converter), an
amplification-level adapter PGA 28 (PGA=programmable gain-amplifier) can
also be included in the input circuit of the analog-digital converter and
of the data acquisition system with the microprocessor or microcomputer
and, in particular, connected to the integrator 29 on the load side.
The task of the microprocessor or microcomputer is, first of all, to
assure, with the help of the digital-analog converter 24, that in a closed
loop of the input circuit, the integrator 29, which in this case can
neither be cleared nor reset, does not become saturated. The measured
value to be determined in a specific measuring interval corresponds then
to the sum of the value of the digital-analog converter and the change in
the integrating signal, in view of the scale factors and offset
(deviations) given by the circuit elements.
The resolution of the response threshold is thereby no longer limited by
the analog-digital converter, but rather, at least with the application of
a PGA 28, only limited, in the case of a defined measuring interval, by
the signal-to-noise ratio of the measuring signal. Optimum noise and
interference suppression is guaranteed by using the processor-controlled,
integrating converter. The invention is most effective for larger
quantities, because the digital-analog converter is much less expensive
than other analog-digital converters of the same resolution.
As a variation of the exemplified embodiment, the digital-analog converter
24 can be dispensed with, when, in its place, the microprocessor or
microcomputer has pulse-width modulated outputs, which are connected to
the integrator 29.
An advantageous application of the invention is for inertial systems, in
particular optical-fiber gyroscopes. As a rule, these systems have three
outputs for the three space axes, and they are advantageously operated in
parallel with several input circuits, in this case three. If one wants to
integrate the digital output signal, in this case, for example, of a rate
of rotation, whose time-related integration first supplies a course
(positional) angle, then the result is not adversely affected by scanning
errors or poor resolution of the analog-digital converter.
One of skill in the art, of course, can modify this exemplified embodiment
without abandoning the general principle of the solution according to the
invention.
In the foregoing specification, the invention has been described with
reference to specific exemplary embodiments thereof. It will, however, be
evident that various modifications and changes may be made thereunto
without departing from the broader spirit and scope of the invention as
set forth in the appended claims. The specification and drawings are,
accordingly, to be regarded in an illustrative rather than in a
restrictive sense.
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