Not Applicable
1. Field of Invention
This invention pertains to a system for monitoring a selected zone. More particularly, this invention relates to a system for monitoring, optionally and distinguishing between, occurrences along one or more piezoelectric cables defining a monitored zone.
2. Description of the Related Art
Residential and light commercial security systems have become an increasingly popular addition to many homes and businesses. These systems are typically based on the electronic detection of a structure. These systems generally classify any input as an event, whether the input is a system message, a detected breach of a perimeter, a detected breach of an interior, or a failure of some part of the security system. The event is analyzed to determine a specific classification, more specifically whether there has been a breach or not. If an event is determined to be in the nature of a breach, it is further classified as being caused by environmental conditions, an animal, a human, or an automobile.
In a residential and light commercial security system a breach is generally detected at either the perimeter or the interior of the structure. The perimeter is typically the outer surface of the structure. The outer surface is almost always breached at the ingress/egress points to a structure such as doors and windows. Breaches at these ingress/egress points are generally detected by magnetic sensors that monitor the opening and closing of doors and windows and by frequency sensors attuned to the sound of glass breakage. Interior breaches are generally detected by heat and motion detectors that monitor moving objects having a temperature greater than the ambient temperature. While providing a warning of intrusion, both the detection of ingress/egress and interior breaches occur after the structure has been damaged or entry has been obtained.
In many security systems, motion sensors are used to turn on outdoor lighting, thereby providing a deterrent to intrusion onto the property. However, these sensors are indiscriminate in that they may be triggered by small animals, children, or other moving objects that are not considered security risks. Further, because of the difficulty in accurately setting the range and the imprecise detection zone of each sensor, setting up a comprehensive coverage area limited to the boundaries of one's property is difficult. Finally, it should be noted that while the external sensors can be connected to a central alarm system, the inability to discriminate between legitimate security risks and stray animals and the difficulty in defining the protection area render such a system unreliable.
A monitoring system for detecting and providing notification of events using one or more piezoelectric cables is shown and described. The monitoring system utilizes a plurality of piezoelectric cables to define one or more zones. These zones often fully enclose a selected are but may need not fully bound the selected area to be effective. Each piezoelectric cable generates an electrical signal in response to a mechanical stress, such as a compression, pressure, torque, or stress.
At least one piezoelectric cable is arranged to define one or more zones so that any approaching object, such as a human, an animal, or a car that exerts a mechanical force on the ground proximate to a zone causes a response in one or more of the piezoelectric cables. Each piezoelectric cable communicates with a base unit that is responsive to the electrical signals produced by the piezoelectric cable(s) in response to the mechanical force, i.e., an intrusion event. In response to the intrusion event, the base unit communicates the event occurrence to a person or to an external system, such as a residential and light commercial security system. By using multiple piezoelectric cables, the monitoring system identifies the zone in which the intrusion event occurs. With additional processing, the monitoring system analyzes the magnitude and frequency of the resulting signal to classify the object that produced the intrusion event. This information is available through the notification process.
The above-mentioned features of the invention will become more clearly understood from the following detailed description of the invention read together with the drawings in which:
A piezoelectric cable-based monitoring system for detecting and indicating events occurring proximate to one or more piezoelectric cables that define one or more zones is shown and described. The piezoelectric cable-based monitoring system, or monitoring system, is generally referenced as 10a and 10b in description and the accompanying figures. The monitoring system optionally locates and classifies events occurring proximate to the piezoelectric cable(s). The present invention is also useful for alerting a pet owner when their pet leaves a containment area and for self-calibrating to adjust for changing conditions.
Events occurring in the area from the base unit 20 to the desired location of Zone 1 would be detected because the piezoelectric cables 13b-g will respond to those events indiscriminately. To avoid this, an additional zone is created by the piezoelectric cable 13a that extends from the base unit 20a to the desired location of the Zone 1. When the additional piezoelectric cable 13a is active, the response from the remaining cables is ignored, thus providing an Ignore Zone within the bounded area 32. Any distinct zone that is created can be monitored or ignored.
Although the zones defined by the piezoelectric cables 13a-13f of the illustrated embodiment enclose the selected area 32, the zones need not form a perimeter. For instance, a plurality of zones defined by linear, parallel, and spaced apart piezoelectric cables allows distance to be gauged on a particular approach path but could be avoided altogether by a different approach path.
The number of piezoelectric cables used determines the number of location zones available. More specifically, the number of zones is controlled by the physical layout and number of the piezoelectric cables, which ultimately determines the number of unique combinations of piezoelectric cables servicing any particular area (zone). For the illustrated layout, the number of zones directly corresponds to the number of piezoelectric cables used.
The working responsive range of a typical piezoelectric cable varies from direct contact (i.e., on the ground surface) to approximately three feet. Although piezoelectric cables may be sensitive to mechanical forces on the ground surface even at depths of up to three feet, the primary use for the present invention is to measure mechanical forces applied to the ground surface. Accordingly, the typical installation depth will be on the shallow end of the range, often only a few centimeters. The performance characteristics of the piezoelectric cable used, the soil composition, and the actual installation depth are factors affecting the sensitivity to mechanical forces of the piezoelectric cable. It should also be appreciated by one skilled in the art that shallower installation depths facilitate easier installation. While various installation depths are contemplated, the foregoing discussion is not intended to limit the disclosure to any particular depth.
Upon receipt of the electrical signals, the processing device 22a determines at least that an intrusion event has occurred and activates an indicator 28 that provides notification of the intrusion. In one embodiment, the indicator 28 is a visual indicator that produces a visually observable signal when an intrusion event occurs. Examples of suitable visual indicators include flashing and/or colored lights providing information about the intrusion event or a display panel providing textual information about the intrusion event. In another embodiment, the indicator 28 is an audible indicator that produces a sound when an intrusion event occurs. In one embodiment, the indicator 28 provides a local notification that requires close proximity to the base unit 20, e.g., within line-of-sight or range-of-hearing. In another embodiment, the indicator is a remote device that can be located at distance from the base unit. The remote device communicates with the processor either through wired or wireless communications, such as an extended length of an electrical conductor or radio frequency communications. The various types of indications, both audible and visual, are usable with either of the local or remote indicators.
The processor 22a is also in communication with an external interface 26 that allows an external system to respond to intrusion events. In one embodiment, the external interface 26 is adapted to interface with a residential and light commercial security system allowing off-site monitoring of intrusion events to occur. In another embodiment, the external interface 26 is adapted to interface with existing objects to provide for notification. One such example is a switchable outlet that allows a table lamp to be turned off and on in response to an intrusion similar to telephone call notification systems used by the hearing-impaired. Another example of the external interface 26 is a telephone jack or network jack to allow the processor 22a to send a text message or e-mail to notify a user of an intrusion event. In a similar fashion, the external interface is a wired or wireless data interface to a personal computer (e.g., USB, Bluetooth®, serial, or parallel connections) that allows personal computer to contact the user by a telephone call, a text message, or an e-mail.
A user interface 38a in communication with the processor 22a to allow the user to set various parameters for the monitoring system 10a. The user interface 38a includes switches, dials, keypads, liquid crystal displays, light emitting diodes, and or other input/output devices to allow the user to communicate the parameters to the processor 22a. In one embodiment, the user interface allows the user to select the zone layout, whether a particular piezoelectric cable is active or not, whether a particular zone is active or inactive, what types of events warrant notification, whether events should be classified, monitoring schedules, and other settings corresponding to the operation of the monitoring system 10a.
In the illustrated embodiment, the base unit includes an input interface 24 that provides the necessary interface to make the electrical signals from the piezoelectric cable(s) 13 accessible to the processing device. Typically, the interface includes an analog-to-digital converter to convert the analog electrical signals into digital representations usable by the processing device 22a. The input interface 24 also includes impedance matching, amplification, and other signal conditioning as necessary and as will be appreciated by one skilled in the art. In an alternate embodiment, the input interface provides a binary interface that indicates which of the piezoelectric cables is active at any given moment.
The block diagram does not illustrate various connections, for example, power and ground connections to the various components; however, those skilled in the art will recognize the need for such wiring and understand how to connect such circuits, based on the components ultimately selected for use.
The next stage of analysis provides an event location function. The stage begins with reading the user settings for the monitoring system 10a. The user settings are read either directly from the user interface or from settings stored in memory that have been adjusted through the user interface. The user settings allow the user to select whether a particular piezoelectric cable is active or not, whether a particular zone is active or inactive, what types of events warrant notification, whether events should be classified, monitoring schedules, and other settings corresponding to the operation of the monitoring system 10a.
A simple user interface allows the selection of one of a limited number of predetermined piezoelectric cable layouts to establish the zones. A more sophisticated user interface allows any piezoelectric cable layout to be specified by the user. Once the piezoelectric cable layout has been configured, the zones are either established manually by the user or automatically by the processing device 22a. Each distinct zone is then configured to be monitored or ignored.
Before proceeding, the first check is to determine in which zone the intrusion event occurred. In general, location is established by evaluating which combination of piezoelectric cables detected the mechanical force and produced a response. Thus, for in the example of
Once the zone in which the intrusion event occurred has been determined, the processing device determines whether a zone is being monitored or ignored. If the zone is being ignored, no further processing of the electrical signal is necessary. If the zone is being monitored, a signature is created. The signature is a set of identifying characteristics from the electrical signal that are used to infer information about the object producing the mechanical force. A simple signature involves only the magnitude of an electrical signal either taken in isolation or averaged over time. A more complex signature contains peak information collected over a period of time. The signature is compared to a set of reference signatures available to the processing device. If the signature cannot be matched to any of the reference signatures to a reasonable degree of certainty, the intrusion event is unclassifiable and the notification stage commences. If the signature matches one of the reference signatures, the type of intruder can be classified. The basic classifications used are quadrapeds, bipeds, and vehicles. One skilled in the art will appreciate that other classifications are available based on the algorithms used.
After analysis, the intrusion event record is compiled and stored. A basic intrusion event record includes the date and/or time that the intrusion event occurred. In other embodiments, the intrusion event record includes zone (location) information and/or classification information. The information in the intrusion event record is stored in temporary or permanent storage depending upon the objectives and capabilities of the monitoring system 10a. The information in the intrusion event record is communicated to the user through the indicator of the monitoring system or to an external device through the external interface.
Optionally, the intrusion event record is tested to determine whether specific notification criteria are met and selectively transmit information to appropriate devices. Not all information need be transferred to all devices. In one embodiment, the processing device 22a selectively communicates intrusion event records to a monitored security system via the external interface. For example, it is desirable to not report animal intrusions to the monitored security system to avoid a police response for every stray animal that wanders through a monitored zone. The ability to ignore or provide notifications at certain times or on certain days is useful. One might choose to ignore vehicles passing through the driveway zone (Zone 2 in
Once processing is completed either by virtue of the intrusion event being below a certain threshold, being in an ignored zone, or being the subject of a notification, the process repeats.
Incidentally, the containment area 32b conforms to the zones defined by the piezoelectric cables 13a-f in the illustrated embodiment, but it is not required that the two area match.
Soil conditions vary with the prevailing environmental conditions, especially variables such as rainfall, humidity, and temperature. As soil conditions change, the response of the piezoelectric film to any particular mechanical force will vary. The embodiment of the piezoelectric security system 10b shown in
The calibration force is detected by the piezoelectric cables 13a-f and received at the base unit 20b as calibration signals. Once received at the base unit 20b, the calibration signals are compared to expected results stored in the base unit memory 44 and adjustments to the monitoring profiles are made based on the differences between the calibration signals and the expected results. This allows the monitoring system to remain reasonably accurate despite changing environmental conditions. The components of the calibration unit 100 are contained within a housing 110 that is environmentally appropriate, i.e., a housing that can withstand moisture, temperature differentials, and moderate physical abuse.
A simpler embodiment of the calibration unit includes only a housing 110 containing the force generator 106 connected to a power supply 108. Activation of the mechanical force generator 106 is accomplished simply by supplying power to the power supply 108. This simplified embodiment requires the base unit 20b to determine when power should be supplied and does not receive instructions from the base unit 20b. The simplified calibration unit, generally, has a limited range of preset calibration forces that it can generate.
A piezoelectric cable-based monitoring system has been shown and described. The piezoelectric cable-based monitoring system uses one or more cables to define a plurality of zones. A unique combination of cables defines each zone. By monitoring activity on the piezoelectric cables, an intrusion event is detected. By determining which of the piezoelectric cables have activity, the unique combination and, therefore, the zone where the intrusion event occurred is determined. The piezoelectric cable-based monitoring system is optionally integrated with a pet containment system to provide both pet containment and premise monitoring functions. The piezoelectric cable-based monitoring system also includes an optional calibration unit that allows the system to adapt to changing environmental conditions.
While the present invention has been illustrated by description of several embodiments and while the illustrative embodiments have been described in detail, it is not the intention of the applicant to restrict or in any way limit the scope of the appended claims to such detail. Additional modifications will readily appear to those skilled in the art. The invention in its broader aspects is therefore not limited to the specific details, representative apparatus and methods, and illustrative examples shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of the general inventive concept.
The present application is a continuation-in-part of application Ser. No. 11/214,522 filed Aug. 30, 2005, which is a continuation-in-part of application Ser. No. 09/522,087 filed Mar. 10, 2000, which issued as U.S. Pat. No. 6,937,647 on Aug. 30, 2005.
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Number | Date | Country | |
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20070120667 A1 | May 2007 | US |
Number | Date | Country | |
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Parent | 11214522 | Aug 2005 | US |
Child | 11626837 | US | |
Parent | 09522087 | Mar 2000 | US |
Child | 11214522 | US |