Severe weather detector and alarm
A compact, portable weather station for predicting local extreme weather conditions and for reporting remote weather conditions. The weather station has sensors for determining local temperature, barometric pressure, humidity, ambient light, and ambient static charge. A microprocessor has memory for storing data relating to past weather conditions and data processing apparatus and algorithms for determining probable developing weather conditions responsive to sensed local conditions. The weather station has a radio receiver for communicating with global weather reporting communications systems utilizing cellular communications. Operating commands, predicted local weather conditions, and remote weather conditions are annunciated in synthesized voice in any one of a variety of predetermined languages. The weather station includes voice synthesizing and recognition apparatus for annunciating verbal prompts and weather conditions, and for responding to vocal control. The weather station is formed in two separable components, one having sensors and the other having radio communications apparatus. REEXAMINATION RESULTS The questions raised in reexamination proceeding No. 90/008,410, filed Jan. 5, 2007, have been considered, and the results thereof are reflected in this reissue patent which constitutes the reexamination certificate required by 35 U.S.C. 307 as provided in 37 CFR 1.570(e) for ex parte reexaminations, or the reexamination certificate required by 35 U.S.C. 316 as provided in 37 CFR 1.997(e) for inter partes reexaminations.
This application is a continuation of Ser. No. 09/246,784 filed Feb. 1, 1999 now U.S. Pat. No. 6,076,044, which is continuation of Ser. No. 08/799,838 filed Feb. 13, 1997, now U.S. Pat. No. 5,978,738.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to an unmanned weather detecting and reporting station. More specifically, the novel station has apparatus for detecting severe weather conditions such as tornadoes and lightning. The station has sensors for sensing certain critical ambient characteristics, a microprocessor for comparing sensed data to a database, a radio for receiving weather data from remote broadcasting sources, and apparatus for broadcasting inferred and reported weather patterns.
2. Description of the Prior Art
Severe weather conditions can arise quite suddenly, with potentially great catastrophic consequences in financial and human cost. To avoid or minimize injury and damage from sudden, violent weather phenomena, it is desirable to be able to predict such occurrences. If weather conditions can be predicted, it is possible in many instances to take steps to mitigate undesirable consequences of the unleashed forces.
An example of a field of activity which could benefit greatly from such analysis and warning of weather conditions is that of aviation. Take off and landing are subject to disruption from extreme weather conditions. Aircraft may be rerouted or their departures and landings postponed if significant threats from weather are identified. Therefore, a need clearly exists for detection and annunciation of extreme weather conditions.
The prior art has suggested a number of weather analysis and warning systems. U.S. Pat. No. 5,105,191, issued to Edgar L. Keedy on Apr. 14, 1992, describes apparatus and method for detecting and indicating severe air disturbances such as shear winds and clear air turbulence. This invention does not address electrical phenomena, as it is primarily intended for providing information essential for take off and landing decisions for advising aircraft pilots. By contrast, the present invention considers different parameters, and detects electrical phenomena such as lightning.
Apparatus and method for identifying tornadoes are set forth in U.S. Pat. No. 5,355,350, issued to Henry E. Bass et al. on Oct. 11, 1994. The subject method employs detection and analysis of ambient sound for amplitude and frequency which may be associated with tornadoes. By contrast, the present invention considers other parameters of ambient conditions, and predicts both tornadoes and also electrical phenomena, such as lightning.
Another tornado detection scheme is seen in U.S. Pat. No. 5,379,025, issued to Frank B. Tatom et al. on Jan. 3, 1995. This invention monitors seismic waves generated by an impending tornado. By contrast, the present invention does not consider seismic phenomena, looking instead to airborne phenomena. The present invention predicts electrical phenomena as well as tornadoes and the like.
U.S. Pat. No. 5,444,530, issued to Ting-I Wang on Aug. 22, 1995, describes a remote monitor for airfields which employs distortion of partially coherent light to detect precipitation and identify the same as rain or snow. By contrast, the present invention monitors different parameters of the atmosphere, notably temperature, humidity, barometric pressure, light, and static charge. The present invention infers presence of extreme weather conditions not analyzed by Wang, such as lightning and tornadoes.
None of the above inventions and patents, taken either singly or in combination, is seen to describe the instant invention as claimed.
SUMMARY OF THE INVENTIONThe present invention combines weather detecting apparatus for detecting local conditions with communications apparatus for obtaining information relating to distant weather conditions. From this combination, a user may ascertain current local conditions which are not apparent to the senses and information regarding imminent or otherwise relevant conditions.
This combination of information enables a person to organize his or her activities appropriately. Detection of severe weather phenomena may cause a person to take actions to protect life and property in the immediate vicinity being monitored. Alternatively, a person may select an appropriate location for travel, if avoidance of local weather is required or if previous travel plans must be modified.
The novel weather station thus both analyzes and reports weather conditions. The communication apparatus enables selection of information from any selected location on the globe, and voice synthesizing apparatus for annunciating selected weather information in a selected language. The voice synthesizing apparatus further is capable of offering operating choice selection prompts in synthesized voice form and of responding to verbal selections by the user.
Preferably, weather conditions being monitored by sensing or by gleaning information from remote radio broadcasts relate to violent or severe conditions most likely to threaten life and property. Ambient characteristics which may be sensed to infer imminent actual weather conditions include temperature, humidity, light intensity, barometric pressure, and potential of ambient static charges. These conditions may then be analyzed by a data processor integral with the weather station to predict imminent weather conditions. The results may be annunciated either by synthesized voice or by indicating lights or the like. In particular, the communications apparatus of the novel weather station is compatible with different international cellular protocols, so that data corresponding to distant weather conditions is obtained by receiving distant local weather condition broadcasts.
The actual apparatus is quite compact, and comprises two separably connected sections. For this reason, the novel weather station is readily portable and easily utilized. A receiver section includes cellular circuitry enabling communications with the external world. A sensor section contains sensors for determining local weather conditions and a microprocessor for accomplishing the various functions of the weather stations. Each of the two separably connected sections has a battery for providing power enabling operation independently of the other respective section.
Accordingly, it is a principal object of the invention to provide a portable weather station which can predict local severe weather conditions.
It is another object of the invention to provide a portable weather station which can obtain information relating to remote weather conditions.
It is a further object of the invention that the weather station be operated to a significant extent by vocalized prompts.
Still another object of the invention is that the weather station be compatible with a variety of languages.
An additional object of the invention is to cooperate with a variety of international cellular protocols.
It is again an object of the invention that the novel weather station comprise two manually separable sections.
Yet another object of the invention is that the novel weather station carry on board a source of power for its operation.
It is an object of the invention to provide improved elements and arrangements thereof in an apparatus for the purposes described which is inexpensive, dependable and fully effective in accomplishing its intended purposes.
These and other objects of the present invention will become readily apparent upon further review of the following specification and drawings.
Various other objects, features, and attendant advantages of the present invention will become more fully appreciated as the same becomes better understood when considered in conjunction with the accompanying drawings, in which like reference characters designate the same or similar parts throughout the several views, and wherein:
Weather station 10 comprises two manually separable sections, including a receiver section 12 having radio communication apparatus therein for communicating with an external cellular radio frequency communication system, as represented by cells 6, and a sensor section 14 containing sensors for sensing local ambient weather conditions. Receiver section 12 also contains a microprocessor 16 and a source of power for operating weather station 10. Sections 12 and 14 are removably connected to one another by structure which will be further described hereinafter.
A relative temperature display 38 indicates local temperature. A proximity sensor 40 detects whether the user is so close to weather station 10 as to interfere with reception of radio signals. An array 42 of light emitting diodes (LED) is utilized to display information regarding mode of operation. A master on-off switch 44 and a reset button 46 are provided. An emergency light 48 and a switch 50 for a purpose described hereinafter are disposed upon the front panel of receiver section 12. Switch 50 is identified by a bas relief or raised symbol 52 for the benefit of the blind. A T-LED 54 is disposed at the bottom of the front panel.
A closure 66 affording access to a battery 67 (concealed in
Referring now to
As shown in
Externally visible or accessible components of weather station 10 have been described thus far. Internal components and circuitry will now be described, with reference first to
Incoming data is received either from sensor section 14 or by radio transmission from remote, external weather data broadcasting sources, as summarized in
Incoming data received from external sources at 800 MHz frequency is processed as follows, referring now to
800 MHz transmissions by weather station 10 are enabled by a transmission module 124 incorporated into the 800 MHz circuitry shown in
Internal components of sensor section 14 are illustrated in
Because sections 12 and 14 are separable, each has an internal antenna 104 (see
Referring now to
Voice simulation apparatus is shown in
Also shown in
Driver 148 drives many of the visual indicators disposed upon the front exterior surface of receiving section 12. These connections are shown in detail in
Array 42 of LEDs comprises three independent groups of LEDS 42A, 42B, 42C. This array indicates mode of operation with respect to gathering of broadcast weather data relating to local weather (LEDs 42A), local continent (LEDs 42B), or international continent (LEDs 42C).
Operation of weather station 10 will now be described. Weather station 10 may be operated in any one of three modes. In a local reporting mode, weather station 10 reports conditions, either with sections 12 and 14 connected or separated. The local reporting mode is indicated by illumination of LEDs 42A. A local continent or country reporting mode is signalled by illumination of LEDs 42B. An international or global reporting mode is signalled by illumination of LEDs 42C. Local reporting may proceed with or without connection of sensor section 14. If connected and delivering data, LED 54 will illuminate.
To operate, it is required that switch 42 be on, that proximity sensors 40 detect a person disposed immediately in front of receiver section 12, and that an appropriate voice command or radio frequency signal be received. When the first two conditions are satisfied, reception of a radio signal indicative of severe weather conditions will initiate operation. Microprocessor 100 (see
If no such correlation is received and the first two conditions for operation are present, a control algorithm will initiate a series of vocalized prompts generated by speech processor 142 and speaker 20 (see
One selection that is made by the user responsive to a prompt is the geographic area that is to be regarded as local. This information may be provided by the user verbally by responding with the latitude and longitude of the selected local area, or with a nearby city and state, according to initial programming of weather station 10.
Certain verbal prompts occur only during initial preparation of weather station 10, and are programmed such that once answered, they will not be repeated at each usage of weather station 10. These prompts concern language selection, as will be discussed hereinafter, and intervals and nature of audible alarms which sound automatically when microprocessor 100 determines that there is a high probability of severe weather conditions. A value relating to threshold of probability of severe conditions may also be included in prompts for initially preparing weather station 10.
When operating in the local reporting mode, sensors 56, 58, 60, 62, 64 periodically sense conditions and transmit collected data to microprocessor 100 for assessment of conditions and annunciation of the same. Routine information such as temperature is indicated on display 30 or relative temperature display 38, which indicates a range rather than specific values, as indicated on display 30. If severe conditions are calculated as probable, an audible alarm in the form of a high pitched tone or a simulated voice message in the selected language is sounded from speaker 20. After the user responds to predetermined verbal prompts to assure that correct selections are made, sensing becomes dormant and will reactivate at predetermined intervals, such as every fifteen minutes.
Memory of weather station 10 is loaded with data corresponding to a selected historic base time period, such as the previous five years. Real time weather data received by antenna 104 is reconfigured by digital-to-analog converter 110 and is routed to microprocessor 100 and to flash ROM 102. Analysis by comparison to known or pre-calculated conditions will generate outputs conducted to visual indicators shown in
Voice recognition utilizes adaptive differential pulse code modulation (ADPCM). Speech processor 142 features low-pass filtering microphone amplifiers with a variable fixed gain ADPCM coder and decoder. Voice recognition device 136 receives a pulse code modulated signal from microphone 18. The signal is low pass filtered, converted to a ten bit digital value and converted to ADPCM. After conversion by the analog-to-digital converter 110, the signal is encoded to a shortened ADPCM code, such as two, three, or four bits. From the analysis circuit, the data is routed to external memory utilizing static RAM device 138 and associated flash ROM device 140. Data is retrieved when microprocessor addresses the voice recognition circuitry.
In the local reporting mode, LEDs 42A (see
LED 54 will illuminate when the local reporting mode is in operation. This serves as warning that only local weather data is being reported.
To select a reporting mode, or to change an existing selection, switch 42 is switched to on, or switched to off followed by switching to on, if weather station 10 is already operating. Predetermined simulated voice prompts will request responses in a preselected code. This may comprise a letter or number corresponding to a particular selection, rather than a value or location being selected.
Language of communication is selected at this time. When a language prompt is answered in a preferred language, all responses by the user thereafter will be treated in the selected language, and all simulated voice prompts will be issued in the selected language. It is preferred that the memory of weather station 10 be loaded to include a range of languages for selection. Preferred languages include English, Spanish, German, French, Russian, Arabic, one or more Chinese dialects, Italian, and Japanese.
Within the U.S., NOAA Weather Radio is monitored for the standard 1050 Hz tone employed by the NOAA to indicate an emergency. Detection of this tone preferably triggers an appropriate alarm and may initiate a simulated vocal query to monitor specific severe conditions, such as identified existing hurricanes, tropical storms, and the like.
When selecting the international or global reporting mode, connection with the appropriate remote cellular protocol is arranged by prompts. Memory of weather station 10 is loaded with available international protocols to assure reception of the requested data.
After certain necessary selections have been made, weather station 10 will issue a general query as to other requirements not addressed by prompts. These may be specified by utilizing a prearranged code or signal.
When initial prompts have been satisfactorily answered, a vocal signal will be issued. Preferably, this signal will be a distinctive sound, such as the Boatswain's Whistle. The Boatswain's Whistle is a melody employed by the U.S. Naval Fleet.
It is to be understood that the present invention is not limited to the embodiments described above, but encompasses any and all embodiments within the scope of the following claims.
Claims
1. A weather station for monitoring weather conditions at at least one remote location comprising:
- a detachable, portable, battery-powered and hand-holdable weather station unit situated at the at least one remote location including: a microprocessor; at least one data sensor coupled to the microprocessor for generating a data signal representative of weather conditions at the at least one remote location; a transmitter coupled to the microprocessor for transmitting said data signal; an antenna coupled to the transmitter, and
- a detachable, portable, battery powered and hand holdable weather station receiver for receiving and displaying the weather conditions received from said weather station unit.
2. The weather station of claim 1 wherein the data sensor monitors the weather data and wherein the transmitter is configured to wirelessly transmit a data signal, said data signal being representative of the weather data monitored at the at least one location.
3. The weather station of claim 1 wherein the data sensor senses temperature.
4. The weather station of claim 1 wherein the data sensor senses wind speed.
5. The weather station of claim 1 wherein the data sensor senses rain.
6. The weather station of claim 1 wherein the data sensor senses barometric pressure.
7. The weather station of claim 1 wherein the data sensor senses ambient light.
8. The weather station of claim 1 wherein the data sensor senses static charge.
9. The weather station of claim 1 wherein the data sensor senses humidity.
10. The weather station of claim 1 wherein the receiver comprises an indicating circuit configured to indicate a temperature trend.
11. The weather station of claim 1 wherein the receiver further comprises an alarm configured to indicate an alarm condition responsive to a comparison of the data signal received by the receiver with a predetermined threshold value.
12. The weather station of claim 1 wherein the receiver further comprises an indicating circuit configured to indicate a signal strength of the data signal being received by the receiver.
13. The weather station of claim 1 wherein the receiver is configured to receive a telemetry signal from a NOAA weather radio.
14. The weather station of claim 1 further comprising an alarm.
15. The weather station of claim 14 wherein the alarm is triggered when a probability of a predetermined weather condition is detected.
16. A weather station for monitoring weather conditions at at least one remote location comprising:
- a portable, battery-powered and hand-holdable weather station unit situated at the at least one remote location including: a microprocessor; at least one data sensor coupled to the microprocessor for sensing at least one weather condition and generating a data signal representative of the at least one weather condition condition at the at least one remote location; a transmitter coupled to the at least one data sensor for transmitting said data signal; and an antenna coupled to the transmitter,
- a portable, battery powered and hand holdable receiver configured to receive the data signal comprising: a storage device configured to store at least one of a plurality of measured remote weather conditions; a processor configured to generate a prediction of a weather condition, the prediction being based on the data signal received by the receiver and at least one of the measured weather conditions stored in the storage device; and an indicating circuit configured to indicate the prediction.
17. The weather station of claim 16 wherein the receiver further comprises an interface configured to receive a latitude coordinate.
18. The weather station of claim 16 wherein the receiver further comprises an interface configured to receive a longtitude coordinate.
19. The weather station of claim 16 wherein the receiver further comprises an interface configured to receive a geographic area latitude position.
20. The weather station of claim 16 wherein the receiver further comprises an interface configured to receive a geographic area longtitude position.
21. The weather station of claim 16 wherein the processor is coupled to the receiver and storage device and configured to generate a prediction of a potential remote weather condition, the prediction being based on the data signal received by the weather station receiver and at least one of the measured weather conditions compared to said stored data.
22. The weather station of claim 16 wherein the prediction of a weather condition is based on the received data signal and at least one of the measured weather conditions stored in the storage device.
23. The weather station of claim 16 wherein the indicating circuit is configured to indicate a temperature trend.
24. The weather station of claim 16 wherein the receiver further comprises an alarm configured to indicate an alarm condition responsive to a comparison of the data signal received by the receiver with a predetermined threshold value.
25. The weather station of claim 16 wherein the indicating circuit comprises a signal strength indicator configured to indicate a signal strength of the data signal being received by the receiver.
26. The weather station of claim 1 wherein the receiver is configured to receive a telemetry signal from a NOAA weather radio.
27. The weather station of claim 14 wherein the alarm is triggered when a predetermined weather condition is detected.
28. The weather station of claim 16 further comprising an alarm.
29. The weather station of claim 28 wherein the alarm is triggered when a predetermined weather condition is detected.
30. The weather station of claim 28 wherein the alarm is triggered when a probability of a predetermined weather condition is detected.
31. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable weather display unit including: a first receiver configured for receiving data via a first radio frequency signal from a source; a second receiver configured for receiving a second radio frequency signal from a cellular telephone network and compatible with an international cellular protocol, wherein the cellular telephone network is different than the source; a display, including a prompt, and configured to display a date and a time; a processing device configured for a) enabling display of information based on received data of at least one of the first radio frequency signal and the second radio frequency signal via the prompt, b) selecting between a first mode of operation that displays first weather conditions including temperature at a first location and a second mode of operation that displays second weather conditions at a second location different than the first location, c) and displaying a prediction of a future weather condition.
32. The apparatus of claim 31, wherein displaying the prediction of a future weather condition occurs during the display of the first weather conditions.
33. The apparatus of claim 31, wherein the prompt enables a location to be selected, the first weather conditions are weather conditions for the location, and at least one of the first weather conditions is based on the received data of the first radio frequency signal.
34. The apparatus of claim 31, wherein the international cellular protocol operates about a fixed frequency.
35. The apparatus of claim 31, further comprising:
- a readily portable, battery-powered and hand-holdable weather station unit including: at least one data sensor for generating a data signal representative of weather conditions at the at least one remote location; and a transmitter for transmitting said data signal via the first radio frequency signal.
36. A portable weather station comprising:
- (a) a portable, battery powered sensor unit, said sensor unit comprising a hand-holdable housing on or in which is provided: a sensor for detecting a local area weather condition; sensor unit circuitry for periodically sampling and wirelessly transmitting digital data of the local area weather condition sensed by said sensor; and a battery power source for powering said sensor unit circuitry; and
- (b) a portable, battery-powered weather station receiver unit, for use with said sensor unit when positioned in a general local area of said sensor unit, said weather station receiver unit including a hand-holdable housing on or in which is provided: first radio frequency receiving circuitry for receiving, from said portable, battery powered sensor unit, said periodically sampled and wirelessly transmitted digital data of said local area weather condition; second radio frequency receiving circuitry for receiving a separate wireless transmission of further digital data transmitted by a remote source which is relatively remotely located in relation to said sensor unit and weather station receiver unit; at least one data storage device; at least one visual display, for displaying numeric and other information-conveying symbols or indications; microprocessor circuitry coupled to the first and second receiving circuits and said at least one data storage device, for receiving said digital data of said local area weather condition and said further digital data, for storing, in said at least one data storage device, said digital data of said local weather condition and said further digital data, and for outputting to said at least one visual display information of said digital data of said local weather condition and said further digital data; and a battery power source for powering said weather station receiver unit.
37. A portable weather station according to claim 36, wherein said separate wireless transmission receivable by said second radio frequency circuitry comprises a transmission over a wireless network.
38. A portable weather station according to claim 36, wherein said microprocessor circuitry is configured to receive and process weather related data from the separate wireless transmission using a protocol compatible with the transmission, and for selecting weather information from a selected region on the globe, the microprocessor being further configured to process encoded weather data.
39. A portable weather station according to claim 36, said weather station receiver unit further comprising a user interface for selecting a mode of operation from a plurality of modes of operation, each mode of operation in the plurality of modes of operation defining different operating characteristics for the weather station receiver unit.
40. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable weather display unit including: a first receiver configured for receiving weather conditions from a weather station unit; a second receiver configured for receiving a signal from a remote source that is different than the weather station unit; a circuit configured for receiving data indicating presence of a user at the weather display unit; a display; and a processing device configured to: receive the weather conditions from the first receiver, receive data representative of the signal from the second receiver, receive the data indicating presence of a user at the weather display unit, based on the data indicating presence of a user at the weather display unit, determine that the weather display unit is to operate in a mode that displays the weather conditions, and in response to the determination, display the weather conditions.
41. The apparatus of claim 40, wherein display of a prediction of a future weather condition occurs during the display of the weather conditions.
42. The apparatus of claim 40, further comprising:
- the weather station unit, wherein the weather station unit is configured to be readily portable, battery-powered and hand-holdable, and the weather station unit includes: at least one data sensor for sensing the weather conditions; and a transmitter for transmitting the weather conditions to the weather display unit via a digital signal.
43. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable weather display unit including: a first receiver configured for receiving weather conditions from a weather station unit; a second receiver configured for receiving a signal from a remote source that is different than the weather station unit; a display including a prompt; and a processing device configured to: receive data representative of the signal from the second receiver, receive data from a user of the weather display unit via the prompt, the received data indicating a selection of a location by the user; identify the location based on the received data; receive the weather conditions from the first receiver; and display a weather prediction for the location based on the received weather conditions and the location.
44. The apparatus of claim 43, wherein the display of the weather prediction occurs during display of the weather conditions.
45. The apparatus of claim 43, further comprising:
- the weather station unit, wherein the weather station unit is configured to be readily portable, battery-powered and hand-holdable, and the weather station unit includes: at least one data sensor for sensing the weather conditions; and a transmitter for transmitting the weather conditions to the weather display unit via a digital signal.
46. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable weather display unit including: a first receiver configured for receiving weather conditions from a weather station unit; a second receiver configured for receiving a signal from a remote source that is different than the weather station unit; a display, including a prompt; and a processing device configured to: receive data representative of the signal from the second receiver, receive the weather conditions from the first receiver, receive location data, via the prompt, identifying a location, subsequent to receiving the location data, receive historical weather condition data corresponding to the location, determine a predicted weather condition by performing a correlation of the weather conditions and the historical weather data, and display the predicted weather condition and one or more of the weather conditions.
47. The apparatus of claim 46, wherein displaying the predicted weather condition occurs during the display of the one or more of the weather conditions.
48. The apparatus of claim 46, further comprising:
- the weather station unit, wherein the weather station unit is configured to be readily portable, battery-powered and hand-holdable, and the weather station unit includes: at least one data sensor for sensing the weather conditions; and a transmitter for transmitting the weather conditions to the weather display unit via a digital signal.
49. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable weather display unit including: a first receiver configured for receiving weather conditions from a weather station unit, the weather conditions representing sensed weather conditions of a first location; a second receiver configured for receiving a signal from a remote source that is different than the weather station unit; a display; a processing device configured to: receive the weather conditions from the first receiver, receive data representative of the signal from the second receiver, select between a first mode of operation that displays the weather conditions received from the weather station unit and a second mode of operation that displays second weather conditions representative of conditions at a second location that is different than the first location, and based on the selected mode of operation, display one or more weather conditions from at least one of the weather conditions received from the weather station unit and the second weather conditions.
50. An apparatus comprising:
- a readily portable, battery-powered and hand-holdable unit comprising: a first receiver configured for receiving data via a first radio frequency signal from a source; a second receiver configured for receiving a second radio frequency signal from a cellular telephone network, wherein the cellular telephone network is different than the source; a display configured to display a date and a time; a processing device configured for a) enabling display of information based on received data of at least one of the first radio frequency signal and the second radio frequency signal, b) selecting between a first mode of operation that displays first weather conditions including temperature at a first location and a second mode of operation that displays second weather conditions at a second location different than the first location, c) and displaying a prediction of a future weather condition.
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Type: Grant
Filed: Jul 21, 2005
Date of Patent: Jan 1, 2013
Assignee: Richmond IP Holdings, LLC (Richmond, VA)
Inventor: Anthony Brown (Hyattsville, MD)
Primary Examiner: Mohamed Charioui
Attorney: Banner & Witcoff, Ltd.
Application Number: 11/186,013
International Classification: G01W 1/02 (20060101); G06F 19/00 (20060101);