Reprogrammable remote sensor monitoring system

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BACKGROUND OF THE INVENTION

This invention relates to a portable, real-time, reprogrammable sensor monitoring system.

For over fifty years, governments have used both active and passive detection systems to track vehicles and troop movements. Intelligence communities have employed multi-million dollar satellite-based sensors including high-resolution cameras, infrared, and radio direction finding equipment to covertly monitor areas of interest. Only recently have the economies of scale and manufacturing breakthroughs permitted using derivatives of this technology for commercial applications.

Early commercial applications were satellite-based vehicle tracking systems using communications satellites in stationary (geosynchronous) orbits above the earth. These systems all employ terminal-antenna packages that are suitcase size and have healthy price tags, and consequently have been limited in use to large trucking firms. To reduce the price and terminal size for general consumer use, there have been two approaches. One employs wireless networks using low-earth orbiting satellites, and a second uses local cellular capabilities and other existing terrestrial wireless networks. With these new capabilities, the mobile asset monitoring and tracking market has grown to include all modes of surface transportation. The current major focus is in vehicle security and stolen vehicle recovery. The lower cost of communications has also permitted the market to expand into small fleet management, as well as navigation, traffic control, and roadside assistance.

Although these capabilities are valuable, the inventor has recognized that they do not address from a personal perspective a problem of increasing importance in society, which nearly everyone encounters during their lives. This problem is based upon the need to monitor a remotely located person or other subject that attempts to function normally but may or may be able to do so; and, if the subject does not function normally, notification must be made and corrective action taken. In a commonly encountered situation, an elderly or infirm relative attempts to lead a normal, independent life, but there is concern that, due to age or infirmity, the relative may not be able to do so. The concerned person may check from time-to-time by calling or visiting, but such checking may be unreliable because the relative may suddenly become ill long before the next check. Moreover, both the relative and the concerned person may be unable to recognize signs of impending distress. Too frequent a telephone call or visit may upset the relative.

There is a need for an approach that will allow a subject to function normally but be monitored and maintain communication as needed for abnormal or emergency situations. The present invention fulfills this need, and further provides related advantages.

SUMMARY OF THE INVENTION

The present invention provides an apparatus and a method for remotely monitoring the status of a living or an inanimate subject. The approach of the invention permits the monitoring of the condition and location of the subject, with interaction by the subject in some cases. The nature of the monitoring may be varied as necessitated by circumstances.

In accordance with the invention, an apparatus for remotely monitoring and assessing the status of a subject includes a portable monitoring unit comprising at least one automatic sensor associated with the subject, a portable-unit location-determining device; and a sensor interface unit. The sensor interface unit includes a programmable microprocessor having an active state and an inactive state. The microprocessor is operable to change from the inactive state to the active state responsive to the occurrence of any of a set of activating parameters for an activation condition including a preselected state of the at least one automatic sensor, a request signal from an external source, and, in the case of a human subject, a status signal by the subject. The microprocessor is in communication with the at least one automatic sensor and the location-determining device. The sensor interface unit further includes a communications device interface in communication with the microprocessor, a first transceiver of a communications device in communication with the communication device interface, and a power supply that provides power to the microprocessor, the communication device interface, and the first terminal of the communications device, as well as any other components of the portable unit that require power.

The one or more sensors are selected appropriately to the subject and the reasons for monitoring the subject. For example, the sensors could include an audio/visual sensor, a biological condition sensor, a chemical sensor, a meteorological sensor, a motion sensor, an electromagnetic sensor, a seismic sensor, or an apparatus sensor.

The location-determining device may either be selected to determine an absolute position of the portable monitoring unit or a relative position of the portable monitoring unit with respect to some other location. The location-determining device is preferably a global positioning system (GPS) receiver, but other types of devices such as triangulation devices or cellular-telephone-based devices may also be used.

Additionally, there is a central monitoring device including a second terminal of the communications device, and, desirably, a display in communication with the second terminal of the communications device and a computer that receives through the communications device and processes information from the sensor interface unit. The central monitoring device is typically able to maintain the necessary communications with a number of the portable monitoring units. The central monitoring device may be portable and may include its own location-determining capability for either an absolute position or a position relative to each portable monitoring unit.

In operation, the microprocessor is programmed with a set of activating parameters for the activation conditions and thereafter enters the inactive state. The microprocessor is activated responsive to the occurrence of the activating parameters of any of the activation conditions. The microprocessor obtains a status of the subject from the automatic sensor and the location of the portable unit from the location-determining device, and sends a status message, through the communications device, to the central monitoring device.

The microprocessor of the sensor interface unit is configured with a unique unit identifier, central monitoring device addressing data, and the initialization data and rules to be employed with each sensor embedded in or interfaced to the unit. The sensor interface unit may be configured on a sensor-by-sensor basis to transmit all sensor data received once activated, or all data meeting certain predefined criteria such as a time window, decibel level, or signal threshold. Data transmission from the sensor interface unit may be initiated manually, activated via a control signal from the central monitoring device, or automatically initiated in response to receipt of specified inputs from one or more of the interfaced sensors. In one embodiment, the sensor interface unit includes an audible tone or visible light generator feature that is activated by a call from the central monitoring device, and a means to activate/deactivate the feature.

The central monitoring device includes the second terminal of the communications device that permits it to communicate with any of a plurality of portable monitoring units, to uniquely identify each unit and the data relative to its configuration and use, to process the data received, and to display the processed data to an operator of the central monitoring device. The position data may be displayed on a map or referenced by distance and bearing relative to a known address or location. The central monitoring device includes the ability to forward the data received to other devices.

Thus, the present invention deals with events from the perspective of the subject being monitored. Events at the portable monitoring unit are sensed. The central monitoring device may make a periodic status query to the portable monitoring unit. The status inquiry may be made in an auto-response mode without the knowledge or participation of the subject, such as the periodic monitoring of sensors when the subject is sleeping or even when the subject is awake so as to be minimally intrusive. The portable monitoring unit may be configured to call in to the central monitoring device either periodically or responsive to preselected sensor readings. The status inquiry may also be made so as to require the response of the subject, for example to determine if an awake subject is mentally capable of responding. In the case of a human subject, the subject may also send a signal such as an "I'm OK" signal to the central monitoring device, either responsive to a page from the portable monitoring unit or upon the subject's own initiative. If the "I'm OK" signal is not received, the system determines the location of the portable monitoring unit, reviews available sensor data such as biological information or sensor information from a medical device used by the person, for example an infusion pump, and provides the information to the concerned person or, as appropriate, summons medical assistance.

A single central monitoring device may monitor a number of different portable monitoring units, each configured differently and reconfigurable as needed. An important feature of the invention is the ability to change (i.e., reprogram) the activating parameters and the functioning of the portable monitoring unit to varying needs. Some of the medical and status applications for human subjects were discussed in the preceding paragraph. The same device, but with different sensors, may be used to track and monitor inanimate objects such as valuable articles during shipment. In that case the sensors may indicate the condition of the article such as temperature, humidity, or movement, or associated equipment such as a refrigerator or heater.

Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention. The scope of the invention is not, however, limited to this preferred embodiment.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a preferred embodiment of an apparatus for remotely monitoring a subject;

FIG. 2 is a block diagram of multiple-user architecture of the communications link of the present invention;

FIG. 3 is a block flow diagram of a preferred method for practicing the invention; and

FIGS. 4-7 are block flow diagrams of the operation of the apparatus.

DETAILED DESCRIPTION OF THE INVENTION

As shown in FIGS. 1 and 2, an apparatus 10 for remotely monitoring and assessing the status of a subject includes a portable monitoring unit 12 and a central monitoring device 14, which may communicate via by a wireless communication link 16. FIG. 1 illustrates a preferred embodiment of the apparatus 10. FIG. 2 illustrates an architecture of the communications link wherein multiple portable monitoring units 12 and central monitoring devices 14 are accommodated.

The portable monitoring unit 12 includes a sensor interface unit 20 having a microprocessor 22 with multiple inputs and outputs, illustrated in a bus architecture. Communication of the microprocessor 22 with the wireless communication link 16, and thence with the central monitoring device 14, is effected through a communications device interface 24 and a first transceiver 26 of the wireless communication link 16. Information is gathered by one or more sensors 28. It is preferred that the wireless communication link 16 be a digital wireless communication link, but an analog link may be used instead. The sensors 28 may include internal sensors 28a embedded in the portable monitoring unit 12 and/or external sensors 28b that are connected to the portable monitoring unit through appropriate external interfaces 30. (In FIG. 1, the external interface 30 is illustrated as part of the portable monitoring unit 12, but it may be external to the portable monitoring unit.) The external sensors 28b may be any type that may be interfaced with the microprocessor 22 through the interface 30. For example, the interface 30 may be a standard serial or parallel interface, a PCMCIA interface, or an Ethernet interface. An external programming device or other device may also be connected to microprocessor 22 through the appropriate external interface 30.

An optional manual input device 32 communicating with the microprocessor 22 is accessible from the exterior of the portable monitoring unit 12, to allow a user or subject of the portable monitoring unit to provide information to the microprocessor 22. The manual input device 32 may be as simple as a switch such as a push button, or more complex such as a keypad. Optionally, a display 34, such as a liquid crystal display, and an audio and/or visual communicator 36, such as a tone generator, speaker, or flashing light, may be provided to signal the user of the portable monitoring unit 12 to take responsive action. An external port 37, such as a serial or a parallel communication port, is provided to permit information or reprogramming instructions to be input to the microprocessor 22 at the site of the portable monitoring unit 12. (A compatible sensor may also be connected through the external port 37.) The manual input device 32, the display 34, the audio and/or visual communicator 36, and external port 37 are each optional features that may be provided for specific applications.

The microprocessor 22 may be a Multi-Chip Package (MCP) such as the currently available Vadem VG330, the Advanced Micro Devices AMD Elan SC400, the NEC HHT-ASSP, or the ZF MicroSystems SMX/386. The microprocessor includes a power management unit which permits the microprocessor to be placed into an inactive state or awakened to an active state by a proper signal. The power management achieves conservation of the power of the power supply 42. The microprocessor is typically provided with memory 44, which may be a random access memory, a readonly memory, a mass storage device, or any combination of these types of memory. This memory may be shared with other components of the portable monitoring unit 12. The first transceiver 26 may be a single-board digital wireless module such as a WIT915 or WIT2500M marketed by Digital Wireless Corporation, with the appropriate interface 24. The first transceiver 26 has its own power management unit that permits the transceiver to be placed into an inactive state or awakened to an active state by a proper signal.

A location-determining device 38 is provided so that the location of the portable monitoring unit 12 may be determined. The location-determining device 38 is preferably a global positioning system (GPS) receiver having an antenna 40 shared with the antenna of the first transceiver 26. The GPS receiver may be a MicroTracker LP global positioning system receiver module available from Rockwell Semiconductor Systems. Other types of location-determining devices 38 such as those based upon cellular cell-site position triangulations, LORAN, and the like, may also be used.

A power supply 42 such as a battery provides power for the components of the portable monitoring unit 12 requiring power, and optionally for the external sensor 28b and the external interface 30. In FIG. 1, the power connections between the powered components and the power supply 42 are indicated by "PS" to avoid the need for drawing the interconnections that would obscure the data-communications paths.

The central monitoring device 14 includes at least a second transceiver 50 of the wireless communication link 16, to establish communications between the first transceiver 26 of the portable monitoring unit 12 and the central monitoring device 14. Typically, the central monitoring device 14 further includes a terminal 52 having a communications device interface 58 to the second transceiver 50, and connections to a display 54 that may be viewed by an operator 56. The terminal 52 may be a simple manual system, or, preferably, it may be a more complex as illustrated. In this more complex terminal 52, there is a computer 60 that communicates with the display 54 and communicates with and oversees the operations of the portable monitoring unit 12 in the manner to be discussed subsequently. The central monitoring device 14 may also be provided with a location-determining device 62, particularly if the central monitoring is movable or portable and its location must be determined. The location-determining device 62 has an antenna 64 shared with the antenna of the second transceiver 50. The location-determining devices 38 and 62 are typically selected to be compatible. If, for example, the location-determining device 38 is an autonomous GPS receiver, the location-determining device 62 normally is also a GPS receiver. On the other hand, the location-determining technique may utilize a triangulation, time-of-flight, or other type of measurement that requires coordination between the location-determining devices 38 and 62, which are then chosen with that technique in mind.

FIG. 2 illustrates an implementation of the apparatus 10 in an existing communications link and its integration with other similar units. In this case, the apparatus 10 is integrated into a cellular telephone comm