Use of optical reflectance proximity detector in battery-powered devices

Abstract

Various methods, systems, and devices for identifying a condition of a battery-powered device are presented. For example, a device may include a smoke detection sensor that detect smokes and, in response to detecting smoke, generate a smoke detection signal. The device may include test circuitry that tests an aspect of the battery-powered device. The device may include an audio output device that outputs a sound in response to the test circuitry determining a particular condition is present. The device may include a proximity detector that monitors for a wave movement of an object within a distance of the battery-powered device and generates a proximity detection signal when the proximity detector detects the wave movement performed by the object within the distance of the smoke detector device.

Claims

1. A battery-powered device, comprising: test circuitry that performs a test on an aspect of the battery-powered device; and a proximity detector that: monitors for a hand being physically waved in a wave movement within a distance of the proximity detector; and generates a proximity detection signal when the proximity detector detects the wave movement of the hand within the distance of the proximity detector, wherein the proximity detection signal generated by the proximity detector causes an indication to be output by the battery-powered device based on the test performed by the test circuitry.

2. The battery-powered device of claim 1, wherein the aspect tested by the test circuitry is a battery charge level of the battery-powered device.

3. The battery-powered device of claim 1, wherein the battery-powered device is a smoke detector.

4. The battery-powered device of claim 3, further comprising: an ionization smoke sensor, an optical smoke sensor, and alarm generation circuitry in communication with the ionization smoke sensor and the optical smoke sensor.

5. The battery-powered device of claim 1, further comprising: a speaker, wherein the indication to be output is an auditory indication that is output via the speaker.

6. The battery-powered device of claim 5, further comprising: a tone generator in communication with the speaker and the test circuitry, wherein the tone generator outputs a tone as the auditory indication to the speaker based on the test performed by the test circuitry.

7. The battery-powered device of claim 1, wherein the proximity detector monitors for the hand being physically waved within the distance of approximately six inches from the proximity detector.

8. The battery-powered device of claim 1, wherein the battery-powered device periodically outputs an auditory indication of a low charge when the low charge is detected by the test circuitry.

9. The battery-powered device of claim 1, wherein the battery-powered device outputs an auditory indication of the wave movement of the hand being detected by the proximity detector.

10. The battery-powered device of claim 1, wherein the battery-powered device comprises a 9 V direct current power supply circuit for powering the test circuitry.

11. A method for identifying a condition of a battery-powered device, the method comprising: monitoring, by a proximity detector of the battery-powered device, for an object being waved in a wave movement within a distance of the proximity detector; generating, by the proximity detector, a proximity detection signal in response to the wave movement being detected within the distance by the proximity detector; determining, by test circuitry of the battery-powered device, the condition is present at the battery-powered device in response to the proximity detection signal; and outputting, by the battery-powered device, an indication of the condition in response to the proximity detection signal and determining that the condition is present.

12. The method for identifying the condition of the battery-powered device of claim 11, the method further comprising: outputting, by a speaker of the battery-powered device, a chirp at a periodic interval indicative of the condition.

13. The method for identifying the condition of the battery-powered device of claim 11, wherein the condition of the battery-powered device that is determined is a battery charge level of the battery-powered device.

14. The method for identifying the condition of the battery-powered device of claim 11, the method further comprising: monitoring, by an ionization smoke sensor of the battery-powered device, for smoke; and monitoring, by an optical smoke sensor of the battery-powered device, for smoke.

15. The method for identifying the condition of the battery-powered device of claim 14, the method further comprising: outputting, by a speaker of the battery-powered device, an auditory indication based on smoke being detected by the ionization smoke sensor, the optical smoke sensor, or both.

16. The method for identifying the condition of the battery-powered device of claim 11, wherein outputting the indication of the condition comprises outputting an auditory indication via a speaker of the battery-powered device.

17. The method for identifying the condition of the battery-powered device of claim 11, wherein monitoring for the object being waved in the wave movement comprises monitoring within a distance of approximately six inches.

18. The method for identifying the condition of the battery-powered device of claim 11, the method further comprising: outputting, by a speaker of the battery-powered device, an auditory indication of the wave movement of the object being detected by the proximity detector.

19. A smoke detector, comprising: an ionization smoke sensor; an optical smoke sensor; alarm generation circuitry in communication with the ionization smoke sensor and the optical smoke sensor; test circuitry that performs a test on an aspect of the smoke detector; and a proximity detector that: monitors for an object being physically waved in a wave movement within a distance of the proximity detector; and generates a proximity detection signal when the proximity detector detects the wave movement of the object within the distance of the proximity detector, wherein: the object is a hand; and the proximity detection signal generated by the proximity detector causes an indication to be output by the smoke detector based on the test performed by the test circuitry.

20. The smoke detector of claim 19, wherein the aspect tested by the test circuitry is a battery charge level of the smoke detector.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a block diagram of a ionization type smoke alarm;

(2) FIG. 2 is a block diagram of an optical type smoke alarm;

(3) FIG. 3 is a more detailed circuit diagram of an optical type smoke alarm;

(4) FIG. 4 illustrates a block diagram of a smoke alarm including proximity sensor operation capabilities according to the present disclosure;

(5) FIG. 5 illustrates the various functionalities associated with the smoke alarm including proximity sensor modes of operation; and

(6) FIG. 6 is a flow diagram describing the operation of the smoke alarm including proximity sensor modes of operation.

DETAILED DESCRIPTION

(7) Referring now to the drawings, wherein like reference numbers are used herein to designate like elements throughout, the various views and embodiments of a smoke alarm having proximity detection operation mode are illustrated and described, and other possible embodiments are described. The figures are not necessarily drawn to scale, and in some instances the drawings have been exaggerated and/or simplified in places for illustrative purposes only. One of ordinary skill in the art will appreciate the many possible applications and variations based on the following examples of possible embodiments.

(8) Referring now to the drawings, and more particularly to FIG. 1, there is illustrated a functional block diagram of a first type of smoke alarm. The smoke alarm of FIG. 1 utilizes ionization detection to detect smoke. The alarm generation circuitry 102 is associated with an ionization sensor 104. The ionization sensor 104 detects particles of smoke using a small amount of radioactive americium 241. The radiation generated by the americium 241 passes through an ionization chamber within the ionization sensor 104. The ionization chamber comprises an air-filled space between two electrodes that permit a small constant current between the electrodes. Any smoke that enters the chamber absorbs the alpha particles emitted by the americium 241 which reduces the ionization and interrupts the current between the electrodes. When this condition is detected, the ionization sensor 104 generates an alarm signal to the alarm circuitry 102 that generates an audible alarm signal that is provided to the speaker 106. Associated with the ionization type smoke alarm is test circuitry 108 that enables testing of the present charge level associated with the battery 110. The battery 110 provides power to the ionization sensor 104, alarm generation circuitry 102, speaker 106 and test circuit 108 to power the smoke alarm.

(9) Referring now also to FIG. 2, there is illustrated an alternative type of smoke alarm circuitry comprising an optical smoke alarm. The optical smoke alarm also includes alarm generation circuitry 202 that is responsive to smoke detection signals provided by an optical sensor 204. The optical sensor 204 includes a light sensor that includes a light source which may comprise an incandescent bulb or infrared LED, a lens to collimate the light into a beam and a photo diode or other photoelectric sensor for detecting light from the light source. In the absence of smoke, the light passes in front of the detector in a straight line. When smoke enters the optical chamber of the optical sensor 204 across the path of the light beam, some light is scattered by the smoke particles redirecting them at the photo diode or photo sensor, and thus triggering generation of an alarm signal to the alarm circuitry 202. The alarm generation circuitry 202 will generate the audible alarm signal to the speaker 206 associated with the alarm circuitry 202. As with the ionization circuit, the optical smoke alarm utilizes a test circuit 208 to test the charge on the battery 210. The battery 210 is responsible for powering all of the components of the optical smoke alarm including the alarm circuitry 202, optical sensor 204, speaker 206 and test circuit 208.

(10) As described previously, some issues arising with existing smoke alarms, be they ionization or optical type smoke alarms, arise from the creation of false alarm situations such as, for example, when a small amount of smoke is created within the kitchen due to burning toast, food falling on the heating element of the oven, etc., or the ability to quickly and easily check the battery charge using the test circuitry. Presently, mitigation of an alarm requires disconnection of the power source to the smoke alarm in order to discontinue an undesired alarm. Additionally, any type of test of the battery charge requires pushing of a button on the external surface of the smoke alarm that requires the user to be able to physically touch the smoke alarm. This often presents a great challenge since either removing power sources to discontinue an undesired alarm or pressing a button to perform battery test operations require the user to get out a ladder or stand on a chair to access the smoke alarm placed in a high location to ensure its optimal performance.

(11) FIG. 3 illustrates a schematic diagram of an optical smoke detection alarm based upon an LDR (light detecting resistor) 302 and lamp 304 pair for sensing smoke. The alarm works by sensing the smoke produced during a fire. The circuit produces an audible alarm from speaker 306 when smoke is detected. When there is no smoke, the light from the lamp 304 falls directly upon the LDR 302. The LDR resistance will be low, and the voltage across the LDR will be below 0.6 volts. Transistor 308 will be turned off in this state and the circuit is inactive. When there is sufficient smoke to mask the light from the lamp 304 falling on the LDR 302, the LDR 302 resistance increases and so does the voltage across the LDR. This will cause the voltage at the gate of transistor 308 to increase and turn on transistor 308. This provides a voltage to power circuit 310 which generates a 5 volt signal to a tone generator 312. The tone signal from tone generator 312 is amplified by an amplifier 314 which is used to drive the speaker 306. Diodes 316 and 318 are used to drop the voltage input to the tone generator 312 from the power circuit 310.

(12) Referring now to FIG. 4, there is illustrated a block diagram of a circuit which enables a user to utilize proximity detection circuitry for temporarily abating an undesired alarm or performing battery test operations rather than using previously described processes. While the implementation with respect to FIG. 4 describes the use of proximity sensor circuitry 402 within an optical type smoke alarm, the proximity sensor circuitry 402 could also be implemented within the ionization type circuitry described hereinabove. The smoke alarm detection capabilities of the smoke alarm of FIG. 4 operate in a similar manner to the optical alarm described previously. Alarm generation circuitry 404 generates alarm signals to a speaker 406 responsive to smoke detection signals received from optical sensor 408. The optical sensor 408 generates the smoke detection signal to the alarm generation circuitry 404 in the same manner as that described previously with respect to the optical smoke alarm of FIG. 2.

(13) The optical sensor 408 in addition to detecting smoke is used for detecting the proximity of a user's hand or other item in conjunction with the proximity sensor circuitry 402. The proximity sensor circuitry 402 detects when a hand or for example, a broom or other item are being waved in close proximity to the smoke alarm. The optical sensor 408 comprises a short-range (approximately 6 inches) optical proximity sensor that in conjunction with the proximity sensor circuitry 402 may be used to control operations of the smoke alarm with either the wave of a hand or some other readily available object such as a broom. The test circuitry 410 enables testing of the charge within a battery 412. The battery 412 provides power to each of the components within the smoke alarm circuit.

(14) Utilizing a combination of the proximity sensor circuitry 402, optical sensor 408 and alarm generation circuitry 404, the smoke alarm may provide a number of proximity controller functionalities. These are generally illustrated in FIG. 5. A number of proximity controlled functions 502 may be provided using the proximity sensor 402. The proximity controlled functions include the alarm mitigation function 504 and the battery test function 506. The alarm mitigation function 504 enables a temporary discontinuation of the audible alarm in situations when an undesired activation of the alarm has occurred. This would occur for example, when a small amount of smoke created within a kitchen that does not indicate a fire or emergency condition has been created. The proximity sensor of the smoke alarm is activated when an object such as a hand or a broom is brought close to the optical sensor 408. If the smoke alarm has been activated due to kitchen smoke or other situations that have been resolved by human intervention, proximity detection would enable the user to disable the smoke alarm for a short period of time, such as 3 minutes, to allow the area around the smoke alarm to air out. A double wave or other more complex detection by the proximity sensor circuitry 402 and optical sensor 408 may be accomplished in a short period of time, such as less than 10 seconds in order to enable assurances that the detection was for a desired mitigation of the alarm and not some type of random event occurring during actual smoke detection.

(15) In order to assist a user in temporarily mitigating the alarm, a momentary change in the audible alarm would be desirable for each proximity event that has been detected by the optical sensor 408 and proximity sensor circuit 402. This would assist the user in knowing whether they had accurately or inaccurately waved their hand or broom in the area of the smoke alarm and provide for an audible indication of aiming feedback with respect to the proximity detection. After the appropriate combination of proximity detection events have been detected by the optical sensor 408 and proximity sensor circuit 402, the audible alarm would be temporarily discontinued.

(16) The smoke alarm commonly beeps at a low duty cycle of around once per minute when the battery 412 has its charge fall below a predetermined level. These beeps can often be very difficult to locate since the beep is short and comprises a single high frequency tone. The beep is short to enable up to a week or more of low battery alerts to be created on an almost depleted battery. The alert transducer uses a single high frequency chirp typically around 3 kilohertz due to the need to produce a very high output from a small transducer. This necessitates the use of a high frequency resonate transducer. Due to the reflections and the use of a half wavelength shorter than the distance between the human ear, it is often very difficult to locate the source requiring the user to check each smoke alarm within the house requiring a great deal of time.

(17) The battery test functionality 506 enables a battery test operation to be performed on the battery 412 within the smoke alarm without having to manually press a button on the smoke alarm. The battery test functionality 506 can be utilized in two situations. When a low battery charge chirp is being emitted by the smoke alarm, the low battery test functionality 506 may be used to determine whether a particular smoke alarm has a low battery charge or whether the battery presently has sufficient charge. The battery test functionality 506 would similarly be useful for performing the periodic battery charge tests that are required to ensure the smoke alarm is in working operation.

(18) By utilizing the proximity sensor circuitry 402, if the smoke alarm has not been activated to indicate detection of smoke, the detection of a single proximity event from a hand or broom by the optical sensor 408 and proximity sensor circuitry 402 initiates a battery check test. If the battery 412 is weak, the test circuitry 410 will cause the production of a distinctive series of beeps or a distinctive tone to indicate a dying battery. If the battery 412 is sufficiently charged, a single short beep of a different tone may be created. Thus, if a user hears a low battery beep, they can use their broom or hand to quickly and easily check all of the smoke alarms within their home without having to climb up on a chair or ladder or remove the devices in order to press a detection button upon the smoke alarm.

(19) As described previously, smoke alarms generally use either an ionization chamber or optical smoke detection circuitry or a combination of both to detect smoke. These differing techniques have distinct advantages and disadvantages. However, a high performance optical reflective detector implemented within the circuit of FIG. 4 including proximity sensor circuitry 402 can readily be adapted to detect reflectance from smoke and to provide proximity detection data since both detections are equivalent low reflectance functions. The proximity detector is more sophisticated since it must deal with ambient light while the conventional optical smoke detector does not have to cancel ambient light since it looks for reflections from smoke in an optically baffled compartment which blocks out ambient light but allows the entry of smoke. A reflectance proximity detector can drive two different LEDs, one for proximity detection and the other for smoke detection within the optical sensor 408. A light pipe can provide a signal from the baffled smoke detector and also from the outside proximity view. Depending on which LED is driven, the proximity detector is either for reflectance above a threshold for either the proximity detection or for smoke and of course giving a different alarm response. Optionally, an auxiliary photo diode can be used for the smoke detector portion to avoid artifacts or issues arising from ambient light. Because the proximity detection technology uses a low duty cycle controller to make proximity detection measurements every second or so, this low duty cycle controller can also be used for the low duty cycle smoke controller which is beneficial for reducing battery charge consumption.

(20) Referring now to FIG. 6, there is illustrated a flow diagram describing the operation of the proximity detection controlled smoke alarm. Initially, at step 602, the optical sensor 408 and proximity sensor circuitry 402 monitor for a proximity actuation. Inquiry step 604 determines whether there has been a detection of a proximity actuation. If not, control passes back to step 602 to continue monitoring for a proximity actuation. Once a proximity actuation is detected, inquiry step 606 determines if the smoke alarm is presently activated. If so, control passes to inquiry step 608 which determines if a predetermined number of proximity activations have been detected. If not, the alarm tone provided by the smoke alarm may be altered at step 610 and control returns back to step 602 to continue monitoring for additional proximity activations. If inquiry step 608 determines that a predetermined number of proximity actuations have been detected, the smoke alarm is disabled at step 612. Inquiry step 614 monitors for the expiration of a selected period of time. If the period of time has not yet expired, the process remains at inquiry step 614. Once the predetermined period of time has expired, control passes to step 616, wherein the smoke alarm is re-enabled and control passes back to step 602 to continue monitoring for proximity actuation. Once the alarm is re-enabled, the smoke detector can monitor for smoke and react accordingly.

(21) If inquiry step 606 determines that the smoke alarm is not presently activated, control passes to inquiry step 618 to make a determination if the battery low alarm is presently active for the smoke alarm. If so, a battery low indication is audibly provided from the smoke alarm at step 620. If the battery low alarm has not been activated, a battery charge check is performed at step 622. Inquiry step 624 determines whether the battery is in a low charge condition. If not, a battery OK audible indication is provided at step 626 to indicate a sufficient charge and control passes back to step 602. If inquiry step 624 determines that the battery is in a low charge condition, the battery low indication is provided at step 620 before control passes back to step 602 to monitor for additional proximity actuations.

(22) The above-described solution provides a low cost intuitive battery alarm control system to limit nuisance alarms within the smoke alarm and enables ease of battery charge checking using a proximity detection control process. The system also improves safety since users often remove batteries or take down smoke alarms that are producing spurious alarms or low battery beeping alarms. Users will also take down unaffected smoke alarms since the user cannot localize the beep associated with the alarm and then do not replace the alarm. Consumers do not check battery levels if the smoke alarm is out of reach. Additionally, use of an optical reflection proximity control system is better than a capacitive proximity system since convenient hand extension devices such as brooms would not work to activate a capacitive sensor which senses a conductive object such as the human hand or body.

(23) It will be appreciated by those skilled in the art having the benefit of this disclosure that this smoke alarm having proximity detection operation mode provides an improved method for controlling operation of a smoke alarm. It should be understood that the drawings and detailed description herein are to be regarded in an illustrative rather than a restrictive manner, and are not intended to be limiting to the particular forms and examples disclosed. On the contrary, included are any further modifications, changes, rearrangements, substitutions, alternatives, design choices, and embodiments apparent to those of ordinary skill in the art, without departing from the spirit and scope hereof, as defined by the following claims. Thus, it is intended that the following claims be interpreted to embrace all such further modifications, changes, rearrangements, substitutions, alternatives, design choices, and embodiments.