KR960036860A - Enhanced system for individual remote control of lighting fixtures at regular intervals - Google Patents

Abstract

A number of interior or other adjustable electrical devices mounted at regular intervals in the ceiling have light emitting sensors mounted within each interior facility and secured to the interior of the interior facility with respect to the photosensitive circuit or to the ballast. The luminescence sensor has an elongated plastic luminescence conduction rod that is sensitive to all angles and extends to or beyond the plane of the interior facility lens positioned without the shadow effect of the internal facility lens reflections. Flexible end optical fiber lenses can be used in place of acrylic rods. The narrow beam emission transmitter selectively illuminates one of the rods or the distal optical fiber lens without illuminating anything else. The photosensitive circuit or ballast in the internal facility can also be controlled by other forms of external dimmer, residence detector, time recorder, photodetector and input device. The luminescence detector or ballast takes up a common housing and shares the same power supply and circuit board. The miniature controller for the luminescence detector operates in 4 of 4 voting modes until a valid signal is detected to open and close the system for 3 of 4 voting modes. New mount connectors for attaching visible light fiber lens cables are specified along with visible light fiber lens cables that conduct infrared light for up to 24 inches.

Description

Enhanced system for individual remote control of lighting fixtures at regular intervals

Since this is a trivial issue, I did not include the contents of the text.

FIG. 1 is a block diagram of an internal lighting fixture adapted to be used with the present invention as modified by a light emitting receiver / ballast control circuit with a remote emission transmitter; FIG. 2 is a front view of a receiver / 3 is a partial cross-sectional view of the second view taken along section line 3-3 in FIG. 2, and also shows in the partially enlarged view a plastic yoke, an interior rear surface and a wire passage cover, a hook and loop clamp 4 is a bottom view of the receiver / ballast control circuit housing of FIGS. 2 and 3; FIG.

Claims (86)

CLAIMS What is claimed is: 1. An optical photosensor system comprising: an interior facility housing adapted to be mounted on a ceiling; an interior facility housing having an interior volume and an open lower portion; a photosensitive stabilizer fixed within the interior volume of the interior facility housing; At least one lamp mounted within the interior volume of the housing and connected to the ballast, at least one lamp extending in a plane across the lower section of the interior facility housing, the interior facility lenses being secured to the interior volume of the interior facility housing A light emitter receiver circuit having a detector, coupled to said light stabilizer in a pivotal manner within said interior facility housing, said light emitter controller comprising therein a light emitter control circuit in response to receipt of an emit signal encrypted by said light emitter, Adjusting the output of the photosensitive ballast against the lamp For controlling the light level of the at least one lamp by regulating an output of the light emitting receiver, the light emitting device being capable of being operated for transmitting light from the disassembled position to the light emitting sensor And a distal end located at a level that is the same as or lower than the lower plane of the internal facility lenses and positioned at a position piercing beyond the plane, and a tip positioned adjacent to the light emitting sensor, Light emitting lenses. 2. The lighting system as claimed in claim 1, wherein the interior equipment housing has a wire passage cover, the wire passage cover has an opening communicating with the light emitting sensor, and the light emitting receiver is fixed to an inner surface of the wire passage cover, And a light emitting diode. 2. The system of claim 1, wherein the elongated luminescent lenses are thin and elongated rods selected from plastic gypsum conducting infrared light emission comprising polycarbonate and acrylic rock. 4. The system of claim 3, wherein the elongated light emitting lenses are thin, elongated acrylic rods. The system of claim 1, wherein the free distal end of the elongated light emitting lenses is operable to receive input encrypted light emission over a wide angle. 2. The system of claim 1, wherein the transmitter is operable to deliver a narrow beam of infrared light with a selected cipher to change a photosensitive state of the at least one lamp. 6. The system of claim 5, wherein the transmitter is operable to impose a narrow beam of infrared light with a password selected to change the photosensitive state of the at least one lamp. 7. The system of claim 6, wherein the narrow beam is 8 degrees. The light emitting diode receiver of claim 1, wherein the light emitting receiver circuit has a wall box insulated housing with a plastic yoke lid fixed thereon and is located across the luminescent sensor, the yoke lid being registered with the luminescent sensor, Wherein the photodetector circuit is mounted on a circuit board having the light emitting sensor and the circuit board is supported across the interior of the wall box housing and is generally parallel to the normal yoke cover. 10. The apparatus of claim 9, wherein the interior housing has a wire passage cover, a second hole formed in the wire passage cover, and fixing means for mounting the light emitting receiver circuit on the inner surface of the wire passage cover, And is connected to the hole in the yoke. 11. The system of claim 10, wherein the securing means for mounting the light emitting receiver circuitry on the inner surface of the interior equipment housing comprises an adhesive tape having double sides. 2. The system of claim 1, further comprising a plurality of the interior fixtures, a light stabilizer, a lamp, and a light emitting receiver, each of the interior fixtures being spaced from each other at least two feet above the ceiling in all directions A photo-sensitive system. 4. The system of claim 3, further comprising a plurality of the interior fixtures, a light stabilizer, a lamp, and a light emitting receiver, each of the interior fixtures being spaced from each other at least two feet above the ceiling in all directions A photo-sensitive system. An electronic device according to claim 1, further comprising external switch means mounted remotely relative to the interior equipment housing and operable to change the output of the dimmer control circuit and to the dimmer control circuit, And is operable to invalidate the operation of the light emitting transmitter. 15. The system of claim 14, wherein the internal switch means is at least one device selected from the group consisting of an on-off switch, a residence sensor, a time recorder and a central relay. An interior facility housing adapted to be mounted on a ceiling, an interior facility housing having an interior volume and an open bottom, a photosensitive stabilizer fixed in the interior of the interior facility housing, At least one lamp connected to the ballast, a generally planar inner facility cover extending in a plane across the lower portion of the inner facility housing, a light emitting receiver circuit fixed within the inner facility housing and having a light emitting receiver, For controlling at least one lamp responsive to receipt of an emit signal encrypted by the emitter sensor, wherein the at least one lamp is coupled to the light stabilizer within the interior facility housing, The light emission that can be operated to regulate the output And a portable hand-operated luminescent light source for delivering luminescence from a location below the inner housing to the luminescent sensor for adjusting the light level of the at least one lamp by regulating the output of the luminescent receiver. A transmitter and a distal end positioned adjacent to the detector extending through an aperture in the interior fitting cover such that the free distal end thereof is positioned to maximize direct ray of light emission at the free distal end of the lenses Wherein the first and second light emitting lenses are formed in combination with thin and long light emitting lenses. 17. The system of claim 16, wherein the transmitter is operable to deliver a narrow beam of infrared light having a selected cipher for changing a photosensitivity state of the at least one lamp. 18. The system of claim 17, wherein the narrow beam is 8 degrees. 17. The system of claim 16, wherein the light emitting receiver circuit has a wall box insulated housing having a plastic yoke lid fixed thereon, the yoke lid having holes therein therein registered with the luminescent sensor, Wherein the circuit board is mounted on a circuit board having a light emitting sensor and the circuit board is supported on the yoke cover and is generally parallel to the yoke cover. 17. The system of claim 16, wherein the elongated light emitting lenses are thin, elongated plastic rods. An optical system comprising at least first and second interior lighting fixtures mounted on a ceiling of a room having a height of approximately 8 feet, each of the interior lighting fixtures comprising a respective light detector circuit and a light emission sensor, And the output light of each of the second illumination interior facilities can be adjusted by illuminating the light emission sensor having infrared light emission, and the light emission sensor can be controlled by the infrared light emission, which extends beyond the surface of the illumination interior facility exposed to the illumination by the infrared light emission Wherein the first and second lighting fixtures are spaced at a distance of greater than two feet and the portable light emitting transmitter has an output infrared beam having a beam angle of about 8 degrees, Each having a receiving angle greater than about 30 degrees, whereby said first or second lighting interior facility Wherein the light emitting detectors of the two are capable of being illuminated by the output beam of the light emitting transmitter without illuminating the other. 22. The system of claim 21, wherein each of the luminescence sensors comprises an elongated plastic rod having a distal end fixed at a location adjacent each of the luminescence sensors and a free distal end at an exterior location of the interface of the fraudulent interior features Optical system. A light emitting receiver for receiving and processing an infrared signal, the light emitting receiver comprising: an infrared reaction circuit component; and an infrared receiver coupled to the infrared response component for generating an output related to signal information contained in the infrared signal received by the light emitting receiver An infrared conducting member extending through the housing and being supported by the housing and having a fixed distal end located adjacent to the infrared reactive circuit component, and an infrared conducting member extending outwardly from the housing for receiving an infrared signal, And a free end. The light emitting receiver according to claim 23, wherein the infrared conducting member is a plastic rod. The light emitting receiver according to claim 24, wherein the plastic rod is vertical. 25. The light emitting receiver of claim 24, wherein the plastic rod has at least one bend in it. The light emitting receiver of claim 24, wherein the fixed tip has a radius of curvature and the free tip is a square lying in a plane perpendicular to an axis of the rod. 24. A light emitting receiver according to claim 23, wherein said elongate member is rotatable about its axis. 29. The light emitting receiver of claim 28, wherein the stationary tip has a radius of curvature and the free tip is a square tip in a plane perpendicular to the axis of the rod. 27. The light emitting receiver of claim 26, wherein the elongate member is rotatable about its axis. 24. The light emitting receiver of claim 23, wherein the elongated infrared conducting member is a flexible distal optical fiber lens adapted to conduct visible light and having a length of less than about 24 inches. 32. The light emitting receiver of claim 31, wherein the flexible end optical fiber lenses are comprised of a gel core surrounded by a light reflection layer and by an outermost ultraviolet-opaque layer. 29. Apparatus according to claim 28, further comprising support means for supporting said elongated, infrared conducting member, said support means being arranged such that said flange and said clamp are spaced axially from each other by a thickness of said wall, Wherein the clamps are pushed through the hole in the wall with the flange trapped against the surface of the wall opposite the surface engaged by the clamps And the light-receiving element. 32. The apparatus of claim 31, further comprising a ceiling tile support structure for supporting said free distal end of said elongated infrared conducting member, said support structure having an elongated cylindrical sleeve having a flange at one end thereof, Said cylindrical sleeve having its flange extending through a ceiling tile and being pressed down on one surface of said ceiling tile, said trimming member having its stem and said slidable trim member received at the free end of said cylindrical sleeve, Wherein the free end of the elongated conductive member extends through the center of the flange, the cylindrical sleeve and the trim member, whereby the top of the ceiling tile, which receives the trim member, And is exposed to external light emission from the surface of the tile Emission receiver 35. The light emitting receiver of claim 34, wherein the cylindrical sleeve tip opposite the flange has a serrated outer surface that is modified to cut a circular hole through a ceiling tile that receives the cylindrical sleeve. ≪ Desc / . A structure for forming a hole through a body that is thin, flat, rigid and sawable, said structure having an insert sheath with an elongated cylindrical sleeve having a flange at one end thereof, The tubular sleeve having its flange extending through the body and being pressed down against the surface of the boat, the trim member having a flange extending through the body Said free end of said cylindrical sleeve having a serrated outer surface adapted to cut a circular hole through said body, said free end of said cylindrical sleeve having an outer surface with a toothed serration adapted to cut a circular hole through said body, Shaped outer surface is covered by the trim member Lt; / RTI > 37. The light emitting receiver of claim 36, wherein the body is a ceiling tile. The light emitting receiver according to claim 1, wherein the photosensitive ballast and the light emitting receiver circuit are mounted in a common housing. 39. The light emitting receiver of claim 38, wherein each of the light stabilizer and the light emitting receiver has a power supply input and a single common power supply coupled to the power supply input for the light stabilizer and the light receiver. A combination of an adjustable light stabilizer circuit and a luminescence reaction control structure as a component, wherein the luminescence reaction control structure comprises a luminescence sensor, wherein the ballast circuit and the luminescence, reaction control structure are extended Wherein the ballast circuit and the luminous reaction regulating structure are each connected to a respective power supply input terminal and to the power supply input terminal of the ballast circuit, Connected common signal power supply circuit and the emission reaction control structure. 41. The adjustable light stabilizer circuit of claim 40, wherein the common housing has a hole registered with the light emitting sensor, the hole being adapted to pass light emission from the outside of the interior facility belonging to the light emitting sensor Combination with a luminescence reaction control structure as a component. In the process of adjusting the sensitivity of a signal sensor having a stationary state and an operating state, it is necessary to detect an activation signal for an effective signal in contrast to the atmospheric noise, and to make the signal sensor less susceptible to atmospheric noise, Reducing the sensitivity of the signal sensor, increasing the sensitivity of the signal sensor to a subsequent presence of an effective signal, and then reducing the sensitivity of the signal sensor if the valid signal disappears during a predetermined length of time The process of adjusting the sensitivity of a signal detector to. 43. The process of claim 42, wherein the valid signal comprises a sequence of a plurality of high start bits scheduled following a predetermined plurality of data bits. 44. The method of claim 43, wherein each of the bits is a sample of a predetermined number of times and when the signal is first received, the samples for each bit are all matched to the state of the bit opening / And samples less than all samples of consecutive bits are matched during operation in said operating condition. 44. The process of claim 43, wherein the circuit operates with 4 of 4 boots in the quiescent state and works with 3 of 4 boots in the quiescent state. An interior facility housing adapted to be mounted on a ceiling, an interior facility housing having an interior volume and an open lower portion, a photosensitive stabilizer fixed within the interior volume of the interior facility housing, At least one lamp mounted to and connected to said ballast and a common inner wall extending in a plane across said lower portion of said inner housing and capable of being disassembled from said lower portion enabling connection and disassembly of said at least one lamp; A light emitting receiver circuit mounted within the interior volume of the interior housing and having a light emitting sensor; and a photodetector control circuit coupled to the interior of the photosensitive stabilizer of the interior facility housing, In response to receiving the emitted light signal The light emitting receiver being operable to regulate the output of the light stabilizer for the at least one lamp; and a controller for controlling the output level of the at least one lamp from the internal facility housing A hand held light emitting transmitter capable of carrying light to emit light from a distant location toward the light emitting sensor; a front end positioned adjacent to the light emitting sensor; And an elongated luminescent lens having a free distal end located within said interior volume of said inner housing at a location between a plane spaced therefrom and a surface of said inner enclosure cover. 47. The system of claim 46, wherein the interior equipment housing has a wire passage cover, the wire passage cover having an aperture communicating with the light emitting sensor, the light emitting receiver being fixed to an inner surface of the wire passage cover, And a light emitting diode. 47. The system of claim 46, wherein said elongated luminescent lens is a thin, elongated rod selected from the group of plastics conducting infrared light including polycarbonate and acrylic. 47. The system of claim 46, wherein the free distal end of the elongated light emitting lens is operable to receive input enciphered light emission over an entire angle. 47. The system of claim 46, wherein the transmitter is operable to deliver a narrow beam of infrared light with a cipher selected to change the photosensitive state of the at least one lamp. 50. The system of claim 49, wherein the transmitter is operable to deliver a narrow beam of infrared light having a selected cipher to change the photosensitive state of the at least one lamp. 51. The system of claim 50, wherein the narrow beam is 8 DEG. 47. The apparatus of claim 46, wherein the light emitting receiver circuit has a wall box insulated housing secured thereto and having a plastic yoke cover positioned across the light emitter, the yoke cover having a hole therein registered with the light emitter Wherein the photodiode circuit is mounted on a circuit board having the light emitting sensor and the circuit board is supported across the interior of the wall box housing and is generally parallel to the yoke cover. 54. The apparatus of claim 53, wherein the interior housing has a wire passage cover, a second hole formed in the wire passage cover, and fixing means for mounting the light emitting receiver circuit on an inner surface of the wire passage cover, And is in communication with the hole in the yoke. 58. The system of claim 54, wherein the securing means for mounting the light emitting receiver circuitry on the inner surface of the interior facility housing is comprised of a double-sided adhesive tape. 47. The apparatus of claim 46, comprising a housing of a plurality of the interior fixtures, a photosensitive ballast, a lamp, and a light emitting receiver, each of the interior fixtures being spaced apart from each other on a ceiling of at least two feet in all directions A photo-sensitive system. 49. The apparatus of claim 48, further comprising a plurality of the interior fixtures, a light stabilizer, a lamp, and a light emitting receiver, each of the interior features being spaced from each other at least two feet above the ceiling in all directions A photo-sensitive system. 47. The apparatus of claim 46 further comprising external switch means mounted remotely relative to the interior equipment housing and operable to change the output of the dimmer control circuit and connected to the dimmer control circuit, Is operable to negate the operation of the light emitting receiver. 59. The system of claim 58, wherein the external switch means is at least one device selected from the group consisting of an on-off switch, a residence sensor, a time recorder and a central relay system. 2. The system of claim 1, wherein the interior facility lens has a plurality of louvers that extend generally vertically from the interior of the interior facility and stop on a common plane. 47. The system of claim 46, wherein the interior fixture lid is a spectral lens cover, and wherein the free distal end of the elongated light emitting lens is positioned adjacent an inner surface of the lenticular lens cover. 61. The system of claim 60, wherein the elongated light emitting lens is positioned between one side edge of the interior facility lens and the interior facility. At least one lamp mounted on the interior equipment housing and connected to the ballast, and at least one lamp mounted within the interior equipment housing and adapted to be mounted within the interior facility housing, An elongated luminescent lens extending from the exterior of the interior housing to a position adjacent to the luminescent sensor, and a photodetector control circuit in the elongated luminescent lens, the luminescent receiver circuit comprising a detector, The light emitting receiver being operable to adjust an output of the light stabilizer for the at least one lamp responsive to reception of the light; From the bottom of the facility housing And a hand-operated light emitting transmitter for carrying the light emitted toward the light emitting sensor. 64. The system of claim 63, wherein the transmitter is operable to deflect a narrow beam of infrared light having a cipher selected to change a photosensitive state of the at least one lamp. 65. The system of claim 64, wherein the narrow beam is 8 degrees. 64. The method of claim 63, wherein the light emitting receiver circuit has a wall box insulated housing secured thereto and having a plastic yoke cover positioned across the light emitter, the yoke cover having a hole therein Wherein the photodetector circuit is mounted on a circuit board having the light emitting sensor and the circuit board is supported on the yoke cover and is generally parallel to the yoke cover. 64. The system of claim 63, wherein the elongated light emitting lens is a thin, elongated plastic rod. An interior facility housing adapted to be mounted on an interior surface, an interior facility housing having an interior volume and an open lower portion in a plane, a light-sensitive structure, and a light source mounted within the interior volume of the interior facility housing and connected to the light- CLAIMS What is claimed is: 1. A light emitting device comprising: at least one lamp; a light emitting diode mounted adjacent to a volume inside the housing of the interior and having a light emitting sensor, the light emitting diode being connected to the light emitting structure, Said light emitting receiver circuit being operable to respond to said at least one lamp to regulate an output of said light emitting structure with respect to said at least one lamp and to adjust the light output level of said at least one lamp by adjusting an output of said light emitting receiver, From the location away from the facility housing, And a free end positioned at a position that can be illuminated by infrared light from a distal end positioned adjacent to the luminescent sensor and from a remote source. And a long and light emitting lens. 69. The system of claim 68, wherein the lamp is an incandescent lamp. An infrared light transmission structure for transmitting an infrared signal, comprising: a flexible infrared transmission member; and a flexible support wire operatively connected to the conductive member and fixed to the infrared shielding enclosure. The infrared ray transmission structure according to claim 70, wherein the combination of the conductive member, the support wire, and the shield can be bent by a hand. 72. The infrared light emitting transmission structure according to claim 71, wherein the combination of the conductive member, the support wiring, and the shield is bent and then shaped. 73. The infrared emitting transmission structure according to claim 72, wherein the combination of the conductive member, the support wire, and the shield may be repeatedly bent by a hand, and after they each bend, they remain bent. 70. The combination of the infrared ray transmission structure and the infrared ray emission reaction circuit component of claim 70, wherein the infrared ray transmission structure receives the infrared ray emission and supplies it to the infrared ray emission reaction circuit component, Reaction circuit parts. An emissive receiver for receiving and processing an infrared signal, the emitter receiver comprising: an infrared reaction circuit component; an adjustment circuit coupled to the infrared reaction component for generating an output related to signal information contained in the infrared signal received by the light emitting receiver; And a free end extending through the housing and supported by the housing and positioned adjacent to the infrared reaction circuit component and positioned outside of the housing for receiving an infrared signal, And is covered with an infrared shielding cover along its length except for the light shielding cover. 77. The light emitting receiver of claim 75, wherein the infrared blocking cover is an opaque plastic tube. An emissive receiver for receiving and processing an infrared signal, the emitter receiver comprising: an infrared reaction circuit component; an adjustment circuit coupled to the infrared reaction component for generating an output related to signal information contained in the infrared signal received by the light emitting receiver; And a free end extending through the housing and supported by the housing and positioned adjacent to the infrared reaction circuit component and receiving the infrared signal at a location external to the housing, And an infrared ray transmitting member which is covered with an infrared ray blocking cover along its length except for the infrared ray transmitting member and is covered with a light emitting focus structure for focusing an infrared ray signal on the infrared ray transmitting member. 78. The light emitting device according to claim 77, wherein the light emitting focus structure comprises an inverted conical body for focusing an infrared signal coming into the free end of the infrared ray conductive member and an infrared ray shielding case covering the infrared ray conductive member except for the free end thereof . 82. The light emitting receiver of claim 78, wherein the inverted conical body is parabolic in shape. An infrared transmission structure for transmitting an infrared signal, the infrared transmission structure comprising a flexible infrared transmission structure that can be bent by hand and maintains its shape after bending. 83. The light emitting transmission structure according to claim 80, wherein the light emitting transmission structure is a partially polymerized silicon acrylic polymer. Infrared reaction circuit components; And an infrared light transmission structure having a function of transmitting an infrared signal to the infrared reaction circuit component and composed of a flexible infrared ray conductive member. 83. The combination of claim 82, wherein the infrared radiation transmission structure can be bent by hand. 83. The combination of claim 83, wherein the infrared emitting transmission structure has a shape after being bent. 83. The combination of claim 82, wherein the infrared radiation transmission structure is capable of flexing repeatedly by hand and maintaining a curved shape after each bending. 83. The combination of claim 82 wherein the luminescent transmission structure is a partially polymerized silicone acrylic polymer. ※ Note: It is disclosed by the contents of the first application.