The present invention relates to an improved automatic timer for wall-powered applications, and more particularly to a radio navigation satellite system (RNSS) automatic timer adapted to regulate the supply of wall power.
Automatic timers are used in households, businesses and institutions to automatically operate wall-powered electrical appliances, lighting, sprinklers, and so on. One type of automatic timer is used as a substitute for a conventional electric wall switch. This type of automatic timer replaces a conventional wall switch with a timer that has an ability to automatically operate whatever had been previously operated by the wall switch and thus the timer actually controls the wall power to the system or device. Thus, if the conventional wall switch had been used to operate an electrical outlet, the automatic timer can be programmed to automatically turn on and off whatever is plugged into the outlet. Likewise, if the conventional wall switch had been used to turn on a lighting fixture, the automatic timer can be programmed to automatically turn on and off the lighting fixture. A second type of automatic timer plugs-in to an electrical outlet and can be programmed to automatically turn on and off one or more wall power sockets. A third type of automatic timer is used in systems in which the automatic timer switches or modulates converted wall power (typically converted to DC power) to a remote system, subsystem or device such as sprinkler control system. In this type of system, the automatic timer automatically turns on and off sprinklers generally based on time of day. A fourth type of automatic timer is used in self-contained applications to switch wall power or to switch or modulate converted wall power internally to operate subsystems of the application such as an alarm clock. In this type of system, the automatic timer automatically turns on the alarm based on time of day.
As electronics become more miniaturized, it is possible to provide more features and greater functionality in automatic timers, including multiple ON/OFF times, varying ON/OFF times, ON/OFF times relative to sunrise or sunset, etc. However, including such features in an automatic timer can complicate programming, operation and maintenance of the timer by the user. As an automatic timer is provided with more features and greater functionality, it becomes desirable to simplify automatic timer configuration requirements where possible. In addition, in order to maintain the clock state in the event of a power failure, many automatic timers require a battery which complicates maintenance and is not environmentally friendly. It is therefore desirable to reduce where possible the need for user programming, operation (and maintenance and eliminate the need for a battery to maintain the clock state in automatic timers adapted to regulate the supply of wall power.
Meanwhile, it is known to use RNSS receivers, such as global positioning system (GPS) receivers, to regulate the supply of locally generated power in mobile applications. In these mobile applications, the GPS receiver has a non-static location, that is, the receiver moves as part of the application. The primary value of the GPS receiver in these mobile applications is determining location and/or velocity in a timely fashion, such as for navigation or surveying. Several requirements are therefore of primary importance to these mobile applications, including time to first fix, location accuracy and velocity accuracy. Providing an accurate clock and/or accurate frequency is of generally lesser importance.
Capurka et al. U.S. Pat. No. 5,247,440, for example, addresses automated control of a transportation vehicle's lights. This patent targets moving vehicles and lighting control is accomplished by regulating vehicle power to the lights based on location and time of day information received from an RNSS or other wireless communication system. The location information used for the lighting control system is provided from the vehicle's GPS-based navigation system. This patent is adapted to a mobile application and the power controlled based on the GPS input is locally generated vehicle power.
Habu et. al. Japanese Patent Application Publication No. 2000-9821A describes a backlight control system for an LCD display of a handheld GPS receiver in which the backlight of the LCD used to display location and time information from the GPS receiver is switched on and off based on computed day and night time zones in order to extend the life of the LCD display. This patent application describes a mobile GPS device with local battery power being controlled by GPS inputs.
Ui Japanese Patent Application Publication No. 2000-292198A describes a back light control system for an on-vehicle navigation system in which the display brightness is set according to the vehicle's location and the local time of day. This patent application is adapted for a moving vehicle's navigation system and the power controlled by the GPS signals is the vehicle's locally generated power.
Williams et al. U.S. Pat. No. 6,753,842 provides a system and method for controlling the backlight of a wireless handset based on its location and the local time of day derived from a GPS receiver along with the output of a photo sensor. A stated goal is enabling the reduction of power consumption and thus conservation of battery energy. The patent is targeted for a wireless communication device which is a mobile application and the power control of the backlight is local battery power.
Automatic timers are also known for static applications. However, these timers are not known to use an RNSS receiver to regulate the supply of wall power, for example.
The present invention, in a basic feature, comprises an automatic timer having a RNSS receiver, such as a GPS receiver, and adapted to control wall power, and methods therefor. When powered up, the automatic timer computes time, date, and position information based on information received by the RNSS receiver. In the event of a power disruption, the automatic timer automatically re-computes such information upon resumption of power. Through judicious integration of an RNSS receiver into an automatic timer, the need for a user to enter into the automatic timer time, date, and position information is advantageously reduced or eliminated outright. The need for a backup battery to maintain the clock state in the event of a power failure is also eliminated. Moreover, due to the static disposition of the RNSS receiver and the fact that it is the ability to produce an accurate clock that is of primary importance, logic requirements for the RNSS receiver of the present invention are advantageously reduced relative to RNSS receivers for mobile applications. A main requirement of the RNSS receiver of the present invention is high sensitivity to enable indoor reception. The fact that the receiver is static in its location enables additional degrees of freedom for increasing sensitivity of the RNSS receiver. Meanwhile, several requirements important to RNSS receivers for mobile applications, such as time to first fix, location accuracy and velocity accuracy, have decreased significance that substantially reduces logic requirements for the RNSS receiver of the present invention.
An automatic timer in one embodiment of the present invention comprises an RNSS receiver, a power controller adapted to regulate a flow of power from a wall power source based on an operational state and a state controller operatively coupled to the RNSS receiver and the power controller and adapted to control the operational state based at least in part on information received from the RNSS receiver. The RNSS receiver may be a GPS receiver. The power controller may be an AC or DC controller or switch. The automatic timer may be, for example, a wall power outlet timer wherein the power controller is adapted to regulate the flow of power to one or more outlets, a light timer wherein the power controller is adapted to regulate the flow of power to one or more or light fixtures, a sprinkler timer wherein the power controller is adapted to regulate the flow of power to one or more sprinkler systems, a climate control timer wherein the power controller is adapted to regulate the flow of power to one or more climate control units, or a tethered device timer wherein the power controller is adapted to regulate a flow of power to a household device such as a power strip, oven range, coffee maker or alarm clock, that during operation remains tethered with a cord to an wall-powered outlet. The state controller may notify the power controller of the operational state by issuing one or more commands to the power controller. The commands issued by the controller may include one or more “on”, “off” or power level commands generated based at least in part on information received from the RNSS receiver, in response to which the power controller permits the flow of power, inhibits the flow of power or regulates the power level.
These and other aspects of the invention will be better understood by reference to the following detailed description taken in conjunction with the drawings that are briefly described below.
State controllers 112, 212 are configured with power regulation policies. Power regulation policies may be implemented using software, firmware or circuitry and may include, for example, a “dusk-to-dawn” variant for security applications in which a wall-powered application may be preconfigured to turn on at dusk and off at dawn and a ‘business day’ variant in which a wall-powered application remains on during business hours, for example, from 7:00 a.m. to 9:00 p.m., Monday-Friday, or alternatively during non-daylight business hours. Power regulation policies may be configured by the manufacturer or in the field through inputs on user systems 114, 214, for example. Power regulation policies may be rendered active or inactive through inputs on user systems 114, 214.
State controller 312 is configured with power regulation policies. Power regulation policies may be implemented using software or firmware and may include, for example, a sprinkler timing variant in which different sprinkler groups may be preconfigured to turn on and off on particular days and at particular times. Power regulation policies may be configured by the manufacturer or in the field through inputs on user systems 314, for example. Power regulation policies may be rendered active or inactive through inputs on user systems 314.
In
The RNSS receiver functions, state controller functions and power controller functions described herein may be implemented in custom logic, such as ASICs, general purpose logic, such as software programs implemented by general purpose processors, firmware, or a combination thereof.
It will be appreciated by those of ordinary skill in the art that the invention can be embodied in other specific forms without departing from the spirit or essential character hereof. The present description is therefore considered in all respects to be illustrative and not restrictive. The scope of the invention is indicated by the appended claims, and all changes that come within the meaning and range of equivalents thereof are intended to be embraced therein.
This application claims priority to U.S. Provisional Patent Application Ser. No. 60/740,714 entitled “Radio Navigation Satellite System Wall Power Automatic Timer,” filed Nov. 30, 2005, the disclosure of which is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2006/044109 | 11/13/2006 | WO | 00 | 6/21/2007 |
Number | Date | Country | |
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60740714 | Nov 2005 | US |