Electricity: measuring and testing – Magnetic – Magnetometers
Reexamination Certificate
1999-08-30
2001-12-11
Snow, Walter E. (Department: 2862)
Electricity: measuring and testing
Magnetic
Magnetometers
C324S225000, C327S511000
Reexamination Certificate
active
06329817
ABSTRACT:
TECHNICAL FIELD
This invention relates to improvements in sensors that provide or use electrical componentry. Specifically the present invention may be used, and will be described throughout this specification as being used within a magnetic field sensor. However it should be appreciated by those skilled in the art that the present invention has numerous applications outside of magnetic field sensors and reference to the above throughout this specification should in no way be seen as limiting.
BACKGROUND ART
Numerous modern electrical devices rely on sensors to provide information about an environment. These sensors can be electrically driven and in most cases consist of some form of transducer which provides an output signal which can be measured. The output signal measured will vary depending on the value of the parameter that is sensed by the sensor. As the sensed parameter changes, so will the sensed output of the transducer. However, a large number of transducers provide output signals that are not directly or linearly proportional to the parameter sensed. For example, in some instances the transducer output may increase exponentially with a linear increase in the sensed parameter, making it difficult to obtain a quick and clear indication of the sensed parameters value. Usually some form of microprocessor or computer is required to provide a scaling function that allows a final linear output to be displayed by the sensor.
Use of a microprocessor in a sensor creates problems if the sensor is to be used in a particularly harsh environment. For example, if the sensor is to be used in an environment where there is a lot of electrical noise, or where it is possible that high voltages may accidentally be applied to the microprocessor, it is likely that the microprocessor will tend to fail or crash frequently. This can be a large problem as the sensor will fail to work correctly or accurately if the microprocessor is continually malfunctioning.
In some transducers, environmental factors such as, for example, ambient temperature, humidity or pressure may also have an effect on the transducer's measured output. In these cases, environmental conditions may change instead of the parameter measured, prompting a change in the transducer's output and hence possibly creating errors in the sensor output. In such situations, environmental conditions also need to be monitored and accounted for when the final result of the transducer is displayed. This is usually done by providing an additional transducer for each environmental condition of concern and imputing a signal from each transducer to the microprocessor used. Provision for these components further complicates the design and manufacture of such sensors.
In most instances, known sensors as discussed above may include a transducer to measure the parameter of interest and a transducer for each environmental condition which has an effect on the output of the first transducer. The output from each transducer is fed through an analog to digital converter and then into a microprocessor which analyzes the signals obtained and takes into account any errors which may be caused by environmental conditions. The microprocessor will then output a digital signal that is linearly proportional to the parameter measured.
In some instances the microprocessor may also be connected to a memory device such as an EPROM which allows information to be stored and supplied to the microprocessor if required. These memory devices are usually configured to contain the machine language instructions (i.e., the program) which is to be executed by the processor. The EPROM is configured to provide these instructions to the processor every time the processor is powered up.
This approach is relatively costly as a separate transducer and an analog to digital converter is required for each environmental condition monitored and also for the parameter measured. This can greatly increase the size and complexity of sensing probes used to place the transducers used in a region of interest. In addition, if the sensors' output is to be sampled at high speed or frequencies, comparatively expensive and fast electrical componentry will also need to be used in the implementation of the sensor.
Recently, sensor users have also found applications for sensors that provide an analog instead of digitized electrical output. In existing devices this could only be obtained if an additional digital to analog converter was placed at the output of the sensor. However this approach again increases the cost of the sensor and further reduces the speed at which the sensors' output can be updated.
An improved sensor that could be implemented with limited and inexpensive components would be of greater advantage over the prior art. An improved sensor that only required one transducer yet still took account of environmental conditions affecting the transducers operation would also be of great advantage over the prior art. It is an object of the present invention to address the foregoing problems or at least to provide the public with a useful choice.
Further aspects and advantages of the present invention will become apparent from the ensuing description which is given by way of example only.
DISCLOSURE OF INVENTION
According to one aspect of the present invention there is provided a sensor for measuring a parameter, said sensor including at least one transducer adapted to provide an analog transducer signal, and at least one converter adapted to convert said analog transducer signal into a digitized transducer signal, and a memory device associated with the converter capable of receiving said digitized transducer signal directly from said converter, the sensor characterized in that the memory device is configured to provide a digitized output value from a memory location, said memory location being associated with or corresponding to the digitized transducer signal received by the memory device.
According to a further aspect of the present invention there is provided a sensor substantially as described above, wherein the sensor also includes a digital to analog converter associated with the memory device and adapted to receive said digitized output value and convert same into an analog output value.
According to yet another aspect of the present invention there is provided a sensor substantially as described above, wherein the sensor also includes a summation device adapted to receive said analog output value from the digital to analog converter and add same to the original analog transducer signal provided by the transducer, wherein the summation device provides a summed output signal which has a substantially linear relationship to the parameter measured by the sensor.
According to a further aspect of the present invention there is provided a method of operating a sensor substantially as described above, said method of operation characterized by the steps of:
i) providing an analog transducer signal to a converter from a transducer, and
ii) converting said analog transducer signal to a digitized transducer signal, and
iii) supplying said digitized transducer signal directly to the input of a memory device, and
iv) matching said digitized transducer signal to a memory location in the memory device, and
v) transmitting a digitized output value stored within said matched memory location to a digital to an analog converter, and
vi) converting said digitized output value to an analog output value.
According to yet another aspect of the present invention, there is provided a method of operating a sensor substantially as described above, being further characterized by the additional step of adding said analog output value to the original analog transducer signal to provide a summed output signal which has a substantially linear relationship to the parameter measured by the sensor.
A sensor as discussed throughout this specification may be used to measure a particular parameter or value associated with an object or a region. For example, in some embodiments the sensor may be configur
Laws Matthew Edwin
McGill Brett Gordon
Moginine Gummer Robert Hugh
Greer Burns & Crain Ltd.
Group 3 Technology Limited
Snow Walter E.
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