Patent Application
20240411714
Not Applicable.
Not Applicable.
Not Applicable
This invention relates to the field of computer-based instrumentation systems. Specifically, a method and system for the implementation of different instrumentation type functions using a configurable common base module combined with a family of input/output interface modules. More specifically, this invention relates to the usage of a configurable common base module to provide timing/control signals for different input/output interface modules each combining to form a unique instrumentation function or feature. Some example applications of instrumentation functions which can be implemented with the invention include: Data Acquisition, Digital Oscilloscope, Logic Analyzer, Waveform Generator, Pattern Generator, and Serial Protocol Analyzer.
There are many known system configurations used within the modular computer-based instrumentation field. Most of these configurations are based around a mechanical multi-slot chassis with integrated electrical backplane supporting plug-in circuit card modules. Chassis and backplane elements can be proprietary or standards based allowing usage of modules from various suppliers. Backplane standards commonly found within the instrumentation field are VPX, VME, Compact PCI and several others. Various manufacturers offer an assortment of plug-in boards or complete systems used to build up application specific system configurations. One good example is the VME backplane, which supplies power, communication, timing and control signals to multiple plug-in circuit cards. The plug-in circuit cards typically comprise of a network interface, processor and several analog/digital input interfaces configured as a custom instrumentation system. The processor card contains software to sample the analog/digital inputs, perform data statistical operations and output results to the network. In these configurations, the plug-in circuit boards rely on the chassis backplane component for all system infrastructure support.
Another well-known alternative to a backplane based instrumentation system is a configuration whereby individual sensor interface modules are connected to the controlling module in a peer-peer network fashion. Communication network standards commonly utilized within this peer-peer configuration are USB, RS-422, Ethernet, PCI-E, and 4-20ma current loop. The individual sensor interface modules are completely self-contained to include all functionality (power, communication, timing and control) necessary to fully support sensor operation. In these configurations, each sensor can be placed remotely from the computer based on cabling interconnections possible with the peer-peer network topology.
In recent years, instrumentation system configuration has moved towards a more automated approach based on the development of network standards. These systems require modules acting as part of an automatic configuration process to contain self capability descriptive data or driver firmware available to a system controller module by network queries. Multiple standards have been developed by both commercial and open source organizations offering variations in such things as programming language, operating system, network topology and security aspects. As an example, the EtherCAT standard based on Ethernet networking has the capability of automatic configuration. Each module in the network contains a “Slave Information File” containing capability information about device functionality and settings. This file is used by a configuration management function to compile network information in an offline mode prior to operational usage. In comparison, several commercially available application building software development platforms can be used to support manual instrumentation system integration. Other highly embedded implementations utilize custom control software written in C or Python to implement system control. With either of these implementations, commonly the manufacturer of interface circuit cards or modules will provide a low level driver software component manually configured as required. This significantly limits reconfiguration flexibility.
Automatic instrumentation system configuration has been addressed in the prior art for differing levels of component integration. Divjak in U.S. Pat. No. 5,444,644 (22 Aug. 1995) titled “Auto-Configured Instrumentation Interface” describes a system with capability to identify different type of input/output sensor devices connected to its inputs. The input devices are described as physical sensor types for example a RTD, Pressure sensor or Potentiometer. In this implementation, a processor performs a systematic analysis by stimulating the input device to determine the sensor type and capability. This configuration is limited to automatic configuration for input device (sensor) types supported by the interface circuitry and not the input interface itself. Several more recent patents cite this reference but are limited to the same concept of sensor input device automatic configuration.
The next level of component integration addressed in prior art is a self contained input/output interface function coupled between the controlling module and physical sensor. Matsuura in U.S. Pat. No. 6,301,508 (9 Oct. 2001) titled “Automatic Instrumentation System” describes a system of controller and instrument modules connected by a communication line link. The controller module queries each instrument module over the communication link and receives a unique executable control program for module interfacing. These control programs are stored on a memory within each individual instrumentation module allowing the controller to perform an automatic system configuration. This method of configuration is analogous to the method described above whereby each interface module contains configuration information accessed by the control module. Slattery et al in U.S. Pat. No. 10,181,853 (15 Jan. 2019) titled “Configurable Hardware Platform for Measurement or Control” describes a system whereby a control circuit receives configuration information from an interface circuit used to configure the interface circuit. The configuration information is described as a “table” or “information stored in registers or a memory”. Configuration information received by the control circuit contains detailed modes/capabilities supported by the interface circuit thereby requiring a more complicated table or file data structure. Paz Lopez et al in US 2014/0148952 (29 May 2014) titled “Central Node and Terminal Instrumentation Node for Self-Configuring and Secure Building Automation System” describes a distributed network concept whereby instrumentation nodes auto configure with a central control node when added to the system. The automatic configuration steps comprise: 1) an instrumentation node sending unsolicited configuration information to the control note, 2) the control node adding the instrumentation node into the network configuration database, and 3) the control node sending control software to the instrumentation node if required. In all of these type systems, configuration information is transferred from a remote interface module to a control module.
The present invention comprises an instrumentation system configured by a common base module for interface with selectable interface modules each providing a unique instrumentation function or feature. The invention provides an automatic hardware and software reconfigurable implementation by connection of the base module to an input/output interface module. Specific electrical signaling required to support each type of interface module electrical requirements (power, communications, timing and control) are provided by the properly configured common base module. Different interface modules are identified through unique identification information retrieved by the base module and transferred to a host computer. The host computer retrieves configuration information from a database based on the identification information. This configuration information is loaded into the common base module to provide the control/timing interface matching interface module configuration. Examples of general interface modules could provide functions for: Analog Input/Output, Digital Input/Output or Sensor interface. Interface modules also can be designed to implement various application specific types of instrumentation equipment for example: Data Acquisition, Digital Oscilloscope, Logic Analyzer, Arbitrary Waveform Generator, Spectrum Analyzer, Pattern Generator or Serial Protocol Analyzer.
The preferred embodiment system block diagram of the present invention is shown in
Hardware components shown in
A first alternate embodiment of the present invention consists of a common base module coupled to the host computer using an USB serial interface. The common base module is powered by the USB interface or can be supplemented with external voltage source for higher consumption applications. This type of embodiment would support high data rate applications.
A second alternate embodiment of the present invention consists of a common base module coupled to the host computer using an Ethernet serial interface. The common base module is powered by the “Power over Ethernet” feature or can be supplemented with external power for higher consumption applications. This type of embodiment would support high data rate applications.
A third alternate embodiment of the present invention consists of a common base module coupled to the host computer using a PCIe serial interface. The common base module is by external power since the standard PCIe interface does not contain a dedicated power capability. This type of embodiment would support high data rate applications.
A fourth alternate embodiment of the present invention consists of a common base module coupled to the host computer using a RS422 serial interface. The common base module can be powered by the RS-422 interface or supplemented with external voltage source for higher consumption applications. This type of embodiment would support low data rate applications.
A fifth alternate embodiment of the present invention consists of a common base module coupled to the host computer using a 4-20ma current loop interface. The common base module can be powered by the 4-20ma current loop interface or supplemented with external voltage source for higher consumption applications. This type of embodiment would support low data rate applications.
