JP2023138458A5 - Wearable and unobtrusive hearing aids, home automation with soft push over a single POF, and home automation with soft push over two cascading POF cables and surrounding environment - Google Patents

Description

The introduction of opto-switch(es) brought about a major change in the wiring of residential, office, public and other building premises, it is through at least one optical cable, i.e. each of the premises of every premises of a building. It is through selective optical cables that link optical commands through the home controller to each and every load within. As explained below, reporting the electrical power consumed will follow the same pattern by introducing some changes to the ISB and outlets.

Returning from the discussion of clarity to home automation and hearing aids, the main objective of the present invention is to program the light control or the light control light itself by introducing a given code or data about the lighting details. and it contains one of the optical data to process and communicate according to instructions, via cascaded POF optical signals, to turn on or off a given bulb, and further Turn that light bulb on or off by communicating data with the PC for instructions.
Following such clear presentation, record at least one power consumption by at least one device via the cascaded POF including the lighting.

These and other objects and features of the invention will become apparent from the following description of preferred embodiments of the invention with reference to the accompanying drawings.
Figure 1A shows past and present horizontal and vertical ducts, wall boxes, and dropped AC power lines, consisting of live (L) power lines (AC), neutral (N), and ground (G). Figure 1B shows an external view of a currently known hearing aid device and battery charger. Figure 2A shows the current congested lighting power wiring to wall boxes and light switches, illustrating the complexity of handling/installing them within the wall box. Figure 2B shows the removal of the rear cover to expand rear box space, removing it to form a slimmer ISB and occupying new space, resulting in a shorter rear and much less power wiring as shown in Figure 3. Figures 3-3A and 3B show single and dual light control touches (BT) for attaching one or more BLAs to a n-strand (intelligent support box) ISB. Each BLA is linked to CPU access to communicate with a given ISB and linked to a home controller (PC) via a cascaded POF. Figure 4-A shows the dual-break POF cable bent inside the (BLA)40-A. 40-A is a dual cut-off POF linked to light controlled touch, fed from generator 4-8 to link light controlled touch receiver 4-10 via dual coupled POF segments 4-5 and 4-7. shows. Figure 4-B shows the dual-break POF cable bent inside the (BLA)40-B. Finger pressing keypad 40P presses plunger 4-6P, presses onto tact spring 40T (Figure 4C) and removes finger press to reverse the state of BLA in a very short time and restart light control touch Show that. Figure HV shows two sets of optically controlled touch keys 40H-1 to 40H-n containing 40V-1 to 40V-n, both switches shown here are identical switches that can be mounted horizontally and vertically on the ISB. Performs switching. Figure 4C shows different internal structures of curved path and straight optical control touch keys, both of which use POF blocking segment(s), which can be used with other optical fiber segments, or with different plungers 4-6 or 4-16 through fiber segments that can be differently structured or shaped and/or arranged to guide the light that is blocked by the push. FIG. 4D is based on the diameter of the POF, flat or other shaped surfaces, and/or other shaped factors, as shown in FIGS. 4D-1 through 4D-33. Figures 4D-1-13, 4D-20-22, 4D-14A-14n, 4D-30-33, and 4E-1-n introduce a basis for a wide range of actions and or data exchange. Figure 4E1~n introduces the dual push of multiple bidirectional exchange and blocking light control elements 4E1~n for push light control with the ability to receive other data and/or that shows. Applicant has developed a pre-installation system of an optical cable for engaging another cut end of the cable or for engaging an optical receiver, an optical transmitter directly or via other receiving, transmitting and/or pushing elements. represents a further design option. Bidirectional as shown here can be multi-way 4E1-n, as well as multiple supplies, or a single power supply for all, if applicable. Figures 4D-2 to 4D-4 illustrate the introduction of two or more (without limitation) bending and forming POF cables including 4D-2 to 4D-11 to 4E-1. It is capable of any bending from a straight line to a 180° bend, including a range of bends. In addition to the illustrated 4D-1, 4D-8, 4D-12, 4D-13, and 4D-14, each device represents a literal endless number of linking, breaking, cascading, bending, and pushing elements. Figure 5A shows a single push knob on the back of a hearing aid device inserted into a user's ear. Here, the user presses the knob to increase (or decrease) the volume. Figure 5B shows a noisy and crowded restaurant or nightclub where the user is unable to understand or communicate with the waiter. Figure 5C allows self-configuration settings by touching the wearable light-controlled touch keys to adjust various parameters of the wearable hearing aid for understanding conversations and communicating with waiters in a crowded restaurant. Demonstrates a simple process. Figure 6A shows a modified DC plug-in device to the ISB that plugs into the quad space, showing a front, back combination for two singles and one quad. Each of the two outlets is shown as an identical pair and duplex with two plug-in switches and four different DC outlets for newly designed outlets and plugs for home automation. Figure 6B shows a single plug-in switch 6.10 and a double socket 6.16P. This is also a rear view of the cut end of the DC wire and the end of the POF cable. The series and series of devices shown have been adapted to accommodate rear access to the full range of future plug-in power wires and POFs, and can be accessed by hand tools to accommodate the newly improved ISB. It is disconnected and plugged into a modern cascaded power line. Figures 18B, 19A, 19B and 19C show hand tools. Figure 6C introduces a similar quad with a modified rear cover and three electrical wires, +DC, -DC, G, (low speed nearly 1KHz) and two (maximum) fiber optic cables (high speed). ing. 1kHz is used for all electrical environments (curtains, fans, heaters, coolers, lights, entrances, security, etc.) and provides sufficient speed for all home automation operations, including power consumption reporting. Figure 6D details the rear removed from the wall box, the new ground terminal, and the previous sensor link of the former ISB. Figure 7 is a conceptual introduction to the changes made to the wall box and the major changes made to the fit-all ISB, which include horizontal and It is a vertically mounted wall box. Figure 8 is a conceptual introduction to the changes made to the wall box and the major changes made to the fit-all ISB, which include horizontal and It is a vertically mounted wall box. Figure 9A introduces a new innovative combination switch (COS). The COS plugs into the dual ISB outlet space for AC or DC, as shown in Figures 9.1 and 9.3. Figure 9B introduces a new innovative combination switch (COS). The COS is selected from a combination of 1 to 4 switches from 9.4-1 to 9.4-4 that are plugged into two ISBs. FIG. 10A shows the light(s) operated via a lighting cabinet (FIGS. 10A-12) forming an unprecedented home lighting system that operates the lights via a hybrid switch. The illustrated small house with eight lights operated through self-assigned ISBs is simple. The illustrated lighting cabinet 103 can be connected to the lighting cabinet and home controller via a cord that identifies the lighting, via a power cable 103CN, and by two or more combination switches or from 1 to 8 light control touch keys (106). Operates through installed ISB. A lighting cabinet specific code is called by the home controller to turn a given light on and off. Figure 10B shows a relatively large house with two lighting cabinets and 16 lights, which literally means Figure 10 and the number of switches via power cables 103CL and 103CN that link to the home controller and the POF cable (2 Literally identical in every way except for the number of POF cables.) Figure 11 shows a practical installation of central lighting via a home hybrid switch and n light-controlled touch keys, positioned and accessible to operate any of the lights installed in the home. It is something. Figure 12 shows a practical installation of central lighting via a home hybrid switch and n light-controlled touch keys, positioned and accessible to operate any of the lights installed in the home. It is something. Figure 12 is another setup of extended lighting configured through a home controller and three or more (n) lighting cabinets, including n hybrid switches, n light control touch keys, and n Operated by a COS switch, located and accessible to any and all of the lights installed in the home. Set up five rows of eight switches with 5 x 6 or 6 x 7 inches of space, which is enough space for circuit breakers, power transmission, power metering, reporting, and more. The size of 5 x 6/6 x 7 is less than half of an A4 size paper. 13A,B, 14A,B, 15A,B , and 16 show details of a new plug-in outlet similar to the plug-in outlet disclosed in FIGS. 7 and 8 for the following purposes. It offers a variety of plug-in outlets and switches for many countries. Figures 7 and 8 disclose and display the US and Japanese outlets. Figure 13A discloses electrical outlets used in China and Australia. The plug-in device is designed for easy plug-in and easy removal using plug-in hand tools. Figure 13B discloses electrical outlets used in China and Australia. The plug-in device is designed for easy plug-in and easy removal using plug-in hand tools. Figure 14A shows another global power socket newly designed for the US, Japan for easy plug-in connection to the ISB. An ingenious plug-in outlet that includes all outlets shown for use in major countries such as the United States and Japan . Figure 14B shows another global power socket newly designed for Europe and the Middle East for easy plug-in connection to the ISB. A unique plug-in outlet that includes all outlets shown for use in major countries such as Europe and the Middle East. Figure 15A shows a similar switch and socket for plugging into an ISB for use in major countries such as Germany . Figure 15B shows a similar switch and socket for plugging into an ISB for use in major countries such as France. Figure 16 shows similar switches and sockets for plugging into ISBs for use in major countries such as the UK and Hong Kong. Figure 17 shows devices for vertical and horizontal ISBs for horizontally or vertically installed ISBs. All wiring, L, N, and G are provided and no physical connections are required other than the plug-in operation provided with all ISBs. Figure 18A shows a new innovative power terminal structure that does not require screws and uses plug-in technology for all links and contacts in and with the power grid. Figure 18B shows a new innovative cascading wiring system where all power and ground wires are plugged in and no screws are required. Supply mains power to a given cascade connection line by the standard power line specified in the given country, such as 1.6, 2.0, 2.6 mm diameter. Figure 19A shows the elements and self-locking contacts to enable the attachment of power wires by push-in as shown in Figure 18A for standard cable diameters 2.6, 2.0 mm and 1,6 mm, and also for in-out Includes ground wire and hand tools. Note that the diameter may differ depending on the country. FIG. 19B further shows a new socket structure to enable the end of an intelligent support box to be linked with the next cascaded intelligent support box. FIG. 19C shows a safe hand tool for removing locked AC or neutral power lines by simple left/right rotation of the hand tool. Figure 20 shows a bedroom light switch and outlet combination for an on-off switch with a light-controlled push switch or a programmed combination switch. The two lights shown are powered by outlets 414 and 415 directly or through a programmed plug-in hybrid switch or combi switch 401 or 402. FIG. 21 shows another example selection of wearables with multiple wearables. Figure 22A shows the use of light control touch keys with finger touch for speaker selection and self-configuration of the hearing aid via configured and/or self-programmed light control touch keys. There are no restrictions on the use of wearables. FIG. 22B shows the use of light control touch keys with finger touch for speaker selection and self-configuration of the hearing aid via configured and/or self-programmed light control touch keys. There are no restrictions on the use of wearables. FIG. 22C shows the use of light control touch keys with finger touch for speaker selection and self-configuration of the hearing aid via configured and/or self-programmed light control touch keys. There are no restrictions on the use of wearables. FIG. 22D shows the use of light control touch keys with finger touch for speaker selection and self-configuration of the hearing aid via configured and/or self-programmed light control touch keys. There are no restrictions on the use of wearables. Figure 23A shows a simplified wearable element and device, as shown in Figures 22A and 22D, including two speakers, multiple light-controlled light touch keys, and a microphone for configuring the hearing aid for comfort. including. Figure 23B shows a simplified wearable element and device, as shown in Figures 22A and 22D, including two speakers, multiple light-controlled light touch keys, and a microphone for configuring the hearing aid for comfort. including. Figure 24A shows an example of the speaker element and touch lighting equipment required for a hearing aid. Figure 24B illustrates the simplicity of a tie that essentially aids in the manipulation of auditory exploration for deaf infants. Figure 24C shows a one-year-old and newborn baby born with a hearing impairment that requires assistance. Figures 25A, 25A-1 and 25A-2 reiterate the ease of self-configuring details and clearly demonstrate the convenience, veracity, and accuracy that can be achieved through constant self-configuration. Figure 25B shows a preferred embodiment.

It is well known that the function of position indicators is approximate or estimative, where position is estimated based on counting motor rotations and lengths of time. Motor rotation is an incorrect measurement method for calculating curtain-based details such as curtain length. Long curtains use rotating coils with strong windings , but no matter what the measurements are, measurements through the number of rotations are far from "free of error from approximate measurements."

The term "standard size and shape" with respect to the present invention and claims refers to touchpads, such as single switches, hybrid switches, relays, or single touchpads, and other single device accessories. , we also use the term "ren" as a reference to the size and shape of things like intelligent IoT devices.
The terms "run" and "run" are defined as the standard shape and size of a given switching or operating device for at least one given instrument. A series occupies a single mounting space within the ISB. A "single touch key" can include two or more touch keys, one or more icons for a given electrical device.

The doubling of size has allowed the applicant to obtain and connect vertically and horizontally mounted ISBs without modification, as never before. These changes require the reconfiguration of electrical outlets (more than 20 types) in all countries, which the applicant considers to be unique patented items. (See Figures 14A,B, 15A,B , 16 and 17.) This makes such an internal-external construction outlet patentable.

Claims (60)

Comfortable touch on at least one given finger touch surface or on a light blocking finger press surface for self-control of noise generated in the surroundings by a verification process with multiple finger press surfaces or finger touch surfaces A method in which the surfaces are covered with decoration or visible through the body or clothing, wherein the light blocking is determined by a generally thin, flat arrangement by or through at least some of the cascaded or otherwise extended lines of the structure, either a soft push or a continuation of the push, or a given by finger press device(s) or other desirable method;
A given POF line can be attached along the body or bent to surround the central processing unit (CPU), extending from the body's belt line to shoulder line to ear level, and even in private cars and other can be linked with home peripheral device(s) such as related elements of;
Absolute to selectively assist in the position of the body belt or upper legs and shoulders and/or a given set of cascades or other lines that distract the light supply through the extended POF are needed, and they typically include an attached speaker and speaker holder, starting from a small battery space and extending to the space on a given person's shoulders or around their ears.
The two CPUs are the main ones that control the time-sensitive test and identify areas of noise, including human noise, whether it is caused by individuals, groups, or both. is a better option than current attempts to block out the noise;
residential and/or commercial establishments, and/or for further linking via cascaded POF grids, including direct communication such as one of RF and/or IR signals, via cascaded chains; Or there is a need to reduce ambient noise contained in a power cabinet and/or lighting cabinet equipped with a hybrid switch that is installed to be linked to public facilities.
wherein a plurality of intelligent support boxes (ISBs) are configured to link with at least one of said home controller and command converter and/or at least one cascaded POF grid and wireless RF communication in space. Via at least one of a signal and/or an IR signal, it is set to be further notified by a finger press for light blocking, a push and/or a firm press for light blocking, or for self-locking. Using the main body cover;
The ISBs are self-configured to a given set by at least one selector to load detailed status data combining operation and signals for reading the power consumed by each and every load. and they can be a single ISB or a given ISB that communicates a piece of bi-directional signal with the home controller and command converter via a communication circuit or one of the network and radios. directional or bidirectional communication, said method comprising the following steps:
a. Loading said detailed data into a given identified ISB designed and configured containing data identified for allocation to said at least one memory device via said communication circuit;
b. A given identification number and at least one given code and address for identifying the installation location within the unit of each of said ISB(s) on one of the configuration selector and the home controller and/or or configuring via either a handheld loader and/or pad;
c. via communication circuitry or at least one of a home controller grid and network, to a given memory and to a memory included in at least one of a home controller and a command converter, including the identified installation location within said unit; recording the details; and
d. identifying, via said configuration selector and one of the identified loads, each load to be powered by one of said wiring devices, said load being powered by said home controller or said command converter memory; or through one of the handheld loader and a power plug having one of the RFID tags mated to the optical port and the mutual optical port, and the RFID reader is connected to the power socket of the ISB. Each is accessed via a power outlet of the attached wiring device. 10. Claim wherein the grid is a single optical grid for propagating at least two of the optical signals through the POF, including an IR propagating signal that propagates line-of-sight in space. The method described in 1;
The network includes a propagating signal consisting of an optical signal through the POF, a line-of-sight IR signal, and an electrical RF signal in space, and combinations thereof, and is connected to a video intercom monitor, shopping terminal, home automation controller, home automation for communicating with a given point for selecting a given controller selected from the group consisting of a grid distributor, a keypad, a touchpad controller, a handheld controller, and combinations thereof. The optical signal and the electrical signal are bidirectionally converted to interface the propagated optical signal to an electrical signal and the electrical signal to an optical signal via the command converter and one of the automation grid distributors. , the RF signal and the optical signal are bi-directionally converted to interface the RF signal to an optical signal and the optical signal to an RF signal through at least one of the automation grid distributors; 3. The method of claim 2, wherein the ISB exchanges signals corresponding to command and response signals of a given load via the automation grid. said bidirectional signal comprises operational commands for switching on/off and operating at least one given load powered by at least one given electrical wiring device, said at least one given load 2. The method of claim 1, comprising a response for providing one of the controller and command converter with at least one data regarding the state of the controller and one of current drawn and power consumed. said details of a given load powered by a given electrical wiring device having one of said installation locations, one of said codes or addresses, said operating commands and responses, and a given memory and said controller and commands; integrated into a control command stored in at least one memory of the converter, the integrated control command being stored during the initial setup of the system, and upgraded from time to time via said controller, into a single integrated command A claim that enables the propagation of short recall of operational commands and responses through the grid and network, for the given function of the given load at a given location, through an integrated response The method described in Section 4. A particular load powered through the ISB communicates through one of the RF signals in space and one of the optical signals by IR in line of sight with the optical port, load is responsive only to a specific command and response, a given memory and a given memory of the controller and command converter are updated to include the specific command and response, and the ISB is responsive to the specific command and response. 6. The method of claim 5, further configured to communicate commands and responses with the particular load via the controller. Diverse loads powered through the ISB(s) via one of the RF signals in space and via one of the optical signals from the optical port and IR in line of sight. communicating, the various loads react to the various commands and responses, the controller including a given memory and the command converter is updated to include the various commands and responses, and the ISB responds to the various commands and responses; 6. The method of claim 5, further configured to enable communication of only the various commands and responses corresponding to each of the various loads with each of the various loads via the network. said ISBs to support said electrical wiring device selected from the group consisting of manual switches, light interrupts, light control and combination switches, hybrid switches, relays, power outlets, power sockets and combinations thereof; 2. The method of claim 1, comprising a restructured body to unify both horizontal and vertical versions into a single size, shape and capacity. A plug-in device to said ISB(s) performs on/off switching operations of a load powered through a given selected power outlet co-attached to said ISB to power the load. Claim reconstituted to support power outlets and switches mounted by the same push-in for both horizontal and vertical implementation of one of the mounted manual switches and/or hybrid switches, including: Method described in 8. Said residential and commercial facilities include single-family houses, apartments in buildings, hotel rooms and one of several rooms, shops, restaurants, clubs, warehouses in a given area, offices, garages, workshops, school classes and one of a class, a library, a hospital room and at least one of a plurality of rooms, a public building and at least one of a plurality of rooms, and at least one of a location and an area within a factory 2. The touch method of claim 1, wherein the touch method is selected from the group consisting of: Structurally integrated comfort of soft push to light block and finger setting via extended plastic optical fiber (POF) grid with cascaded grid of Intelligent Support Boxes (ISB)(s) , at least one of the operational commands by the home automation controller linked by its cascading POF is a push to the light interrupt, or a push to the hybrid switch; To the home controller for expansion to ISB(s) cascaded via hardened, push-fixed conductors, power wires are live AC power (L), neutral (N), ground (G) for each plugged-in unit within the ISB, with conductors that push and secure the AC power supply to provide upgraded sensing;
Each ISB supports the calculated power delivered to n loads and further measures and reports each power delivered by each of the n loads measured by a given current sensor to the home controller do. Here, at least one optical interruption of the cascaded ISB(s) in the home is one cascade connection in the building, which is residential, public, commercial, factory, school, parking lot, museum, theater, airport and a second optical connection wire of a second cascaded ISB grid for communicating with the home surroundings by RF and/or IR between each facility and the home and vehicle and building surroundings (Figure 19-4A). 19B) for other buildings seeking automation.
Each of the plurality of ISBs loads detailed data related to each configured and installed ISB including a CPU, at least one of a configuration selector, and data related to configuring a home automation grid and wiring devices. a memory for, a circuit for operating and calculating the power consumed by each load via said wiring device, and at least one of said home controller and command converter via one of said home automation grid and network; , comprising a communication circuit for communicating at least one bidirectional signal;
Each ISB includes at least one sensor configured to power n powered devices (at least one), measured in advance or on an ad hoc basis, and at least 1 m/W. providing a current drain sensor measuring at 1 mS and measuring each power due to the load from 1 mW to 30 kW and set to cut-off (power cut-off) provided by the electrical wiring authority of a given country; and The configuration is via said at least one of a configuration selector or a given memory, and at least a controller and a command converter for recording and identifying each of said ISB(s) and their installation location within said unit. into one memory, containing one of the identification numbers and code and address wirelessly via a handheld loader and one of the pads to load the box identifier; and a given ISB powered via a given ISB. a load is identified via one of said selectors and configured to be a load identifier stored in said memory, and one of said optical ports and RFID tags is configured to be connected to a combined optical port and RFID reader, respectively. Accessed via a power outlet of the ISB with the wiring device configured to mate and attached to the ISB. one of an optical grid for propagating at least one of the optical signals through the POF, the grid comprising a low voltage for propagating electrical signals and an IR signal propagating within line of sight in the space; 12. The optical grid of claim 11, wherein the network includes propagation of signals consisting of the optical signal, line-of-sight IR signal, electrical signal, RF signal, and combinations thereof through the POF. a structured, integrated soft push to; and
The controller is further programmed to exchange signals with groups consisting of video intercoms, shopping terminals, keypads, touchpads, handheld controllers, and combinations thereof. The optical signal and the electrical signal are bidirectionally convertible to interface a propagated optical signal with a propagated electrical signal, and the RF signal and the optical signal The RF is bidirectionally converted into an optical signal through the automation grid distributor and one of the ISBs to exchange signals corresponding to command and response signals of a given load. 13. The structured integrated light grid of claim 12. The operating command for a hybrid, combi or optically controlled switch operates at least one given load and includes data relating to the status of at least one of the current flowing through the at least one given load and the power consumption. 12. The structured integrated electrical grid of claim 11, responsive to provide to the controller and command converter: 15. A structured integrated electrical grid according to claim 14, wherein the details of a given load powered by a given power supply device, one of the installation locations and a code and address combination are: The controller and a command converter for storing integrated control commands are randomly upgraded through the controller and enable short recall propagation of operational commands and responses through the grid and network, and a single Operating the predetermined function of the predetermined load at a predetermined location via an integrated command and a single integrated response. the specific load is responsive only to specific commands and responses, a given memory and a given memory of the controller and the command converter are updated to include the specific command and response, and the ISB is 16. The structured integrated electrical grid of claim 15, further configured via the controller to communicate the particular commands and responses with the particular loads. A diverse load powered via the ISB communicates with the diverse load via one of the RF signals, and a given memory and a given memory of the controller and the command converter communicate with the diverse load via one of the RF signals, and a response, the ISB being further configured to communicate, via the controller, each of the various commands and responses commensurate with each of the various loads. Structured integrated electrical grid described. The ISB(s) are horizontal boxes structured with the same size and capacity as the vertical boxes, and capable of carrying manual switches, hybrid switches, relays, power outlets, power sockets, IoT devices, AI devices, and 12. The structured integrated electrical grid of claim 11, wherein the structured integrated electrical grid exceeds the newly introduced identical lateral and vertical size and capacity selected from the group consisting of combinations thereof. said ISB includes on-off switching of a load powered via a given power outlet co-attached to said ISB for powering a load, attached to and directly connected to a hybrid switch; 20. The structured integrated electrical grid of claim 18, structured to turn on and off a loaded load. Said residential and commercial facilities include single-family houses, apartments in buildings, rooms and rooms in hotels, shops, restaurants, clubs, given areas of warehouses, offices, garages, workshops, classes and classes in schools. from one of the following: a library, a hospital room and rooms, at least one of a public building room and rooms, and at least one of a factory compartment and area. 12. The structured integrated electrical grid of claim 11 selected from the group consisting of: A conductive power line consisting of Live AC (L), Neutral (N) and Ground (G), and a single unit linked to at least one Intelligent Support Box(es) or (ISB)(s) plugged in by a finger press. network via one of rigid pushing and fixing or self-crimping to plastic optical fibers (POF) with one cascaded plastic optical fiber (POF) segment, and/or at least one of the cascaded grids. Comfortable touch method to light isolation and/or settings provided through one;
Here, the cascaded POF links with the central processing unit (CPU) and further links with (home controller) - (home automation) - (HCHA);
The ISB can connect a cascaded chain or a single ISB through a cascaded POF grid or by directly communicating one of the RF and/or IR signals commanded by (HCHA). through and for further linking a given n number of switches for the switching of a hybrid switch and for turning on/off at least one light bulb, installed in residential and/or commercial and/or public premises. selected to support electrical wall box(s) and/or n electrical cabinet(s) and/or n lighting cabinet(s);
a plurality of said ISBs are linked to at least one of a home controller, a command converter, via at least one of a cascaded POF grid and at least one of a wireless RF signal and/or an IR signal in space, and further configured to be notified by at least one of a control light and/or a combination signal;
The ISB is self-configurable to a given set to load detailed status data combining operation and signals for reading the power consumed by each and all loads through at least one configuration selector. , it is the communication circuit of a single or multiple ISBs, one-way or two-way of the (HCHA) or two-way signals that communicate with the (HCHA) and the command converter via one of the network and radio and the method consists of the following steps:
a. Loading said detailed data into a given identified ISB designed and configured containing data identified for allocation to said at least one memory device via said communication circuit;
b. a given identification number and at least one given code and address for identifying the installation location within said unit of each of said ISBs, either in a configuration selector and (HCHA); and/or configuring via either a handheld loader and/or a pad;
c. communication circuits and/or via at least one of the (HCHA) grid and network to a given memory and/or to the memory included in the (HCHA) and at least one of the command converter within said unit; recording details including the identified installation location; and
d. identifying, via said configuration selector and one of the identified loads, each load that is powered by one of said wiring devices, said (HCHA) or said command converter; stored in memory or through one of the power plugs having one of said handheld loader and an RFID tag mated to an optical port and a reciprocal optical port, and the RFID reader is connected to the power socket of said ISB. each of which is accessed via a power outlet of said wiring device attached to said wiring device. 21. The grid is a single optical grid for propagating at least one of the optical signals through the POF including an IR propagating signal that propagates line-of-sight in space. The method described in;
The network includes propagating signals consisting of optical signals through the POF, line-of-sight IR signals, electrical signals and RF signals in space, and combinations thereof, and includes video intercom monitors, shopping terminals, (HCHA), home Automation Grid for communicating with push points for selecting a given controller selected from the group consisting of distributor, keypad, touchpad controller, handheld controller, and combinations thereof. The optical signal and the electrical signal are bidirectionally converted to interface the propagated optical signal to an electrical signal and the electrical signal to an optical signal via the command converter and one of the automation grid distributors. , the RF signal and the optical signal are bi-directionally converted to interface the RF signal to an optical signal and the optical signal to an RF signal through at least one of the automation grid distributors; 23. The method of claim 22, wherein the ISB exchanges signals corresponding to command and response signals of a given load via the automation grid. said bidirectional signal comprises operational commands for switching on/off and operating at least one given load powered by at least one given electrical wiring device, said at least one given load 22. The method of claim 21, comprising a response for providing one of the (HCHAs) with at least one data regarding the state of the HCHA and one of current drawn and power consumed. said details of a given load powered by a given electrical wiring device having one of said installation locations, one of said codes or addresses, said operating commands and responses, and a given memory and said controller and commands; The integrated control commands are integrated into the control commands stored in at least one predetermined memory of the converter, and the integrated control commands are stored during the initial setup of the system, and upgraded from time to time via said controller, into a single integrated command. and the given function of the given load at a given location through a single integrated response, allowing short recall propagation of operational commands and responses through the grid and network. 25. The method of claim 24. A particular load powered through the ISB communicates through one of the RF signals in space and one of the optical signals by IR in line of sight with the optical port, load is responsive only to a particular command and response, a given memory and a given memory of said (HCHA)(s) are updated to contain said particular command and response, and said ISB is responsive to said particular command and response. 26. The method of claim 25, further configured via the controller to communicate specific commands and responses with the specific load. Diverse loads powered through the ISB(s) via one of the RF signals in space and via one of the optical signals from the optical port and IR in line of sight. communicating, the various loads reacting to the various commands and responses, a given memory of the controller and a memory of the command converter are updated to include the various commands and responses, and the ISB responds to the various commands and responses; 26. The method of claim 25, wherein the method is configured to communicate with each of the various loads and only the various commands and responses corresponding to each of the various loads. said ISBs to support said electrical wiring device selected from the group consisting of manual switches, light interrupts, light control and combination switches, hybrid switches, relays, power outlets, power sockets and combinations thereof; 22. The method of claim 21, comprising a restructured body to unify both horizontal and vertical versions into a single size, shape and capacity. said ISB(s) and a plug-in device to said ISB to turn on and off a load powered through a given selected power outlet co-attached to said ISB to power the load. Reconstructed to support power outlets and switches mounted by the same push-in for both horizontal and vertical implementation of one mounted manual switch and/or hybrid switch, including switching operations. 29. The method according to claim 28. Said residential and commercial facilities include single-family houses, apartments in buildings, hotel rooms and one of several rooms, shops, restaurants, clubs, warehouses in a given area, offices, garages, workshops, school classes and one of a class, a library, a hospital room and at least one of a plurality of rooms, a public building and at least one of a plurality of rooms, and at least one of a location and an area within a factory 22. The touch method of claim 21, wherein the touch method is selected from the group consisting of: Structurally integrated comfort of soft push to light block and finger setting linked by its cascading POFs via an expanded POF grid by a cascading grid of ISBs At least one of the operating commands by (HCHA) is a push on the light cutoff or a push on the hybrid switch, and said light cutoff is pushed through the reinforced conductor that secures the power wire. To the home controller for expansion into multiple ISBs that are cascaded, the power wires consist of live AC power (L), neutral (N), and ground (G), and the plug-in For each of the units, it has a conductor that presses and secures the AC power supply to provide upgraded sensing;
Each ISB supports the calculated power delivered to n loads and also measures (HCHA) each power delivered by each of the n loads measured by a given current sensor. Report. Here, at least one optical interruption of the cascaded ISB(s) in the home is one cascade connection in the building, which is residential, public, commercial, factory, school, parking lot, museum, theater, airport and a second optical connection wire of a second cascaded ISB grid for communicating with the home surroundings by RF and/or IR between each facility and the home and vehicle and building surroundings (Figure 19-4A). 19B) for other buildings seeking automation.
Each of the plurality of ISBs loads detailed data related to each configured and installed ISB including a CPU, at least one of a configuration selector, and data related to configuring a home automation grid and wiring devices. a memory for, a circuit for operating and calculating the power consumed by each load via said wiring device, and at least one of said home controller and command converter via one of said home automation grid and network; , comprising a communication circuit for communicating at least one bidirectional signal;
Each ISB includes at least one sensor configured to power n powered devices (at least one), measured in advance or on an ad hoc basis, and at least 1 m/W. providing a current drain sensor measuring at 1 mS and measuring each power due to the load from 1 mW to 30 kW and set to cut-off (power cut-off) provided by the electrical wiring authority of a given country; and The configuration is via said at least one of a configuration selector or a given memory, and at least a controller and a command converter for recording and identifying each of said ISB(s) and their installation location within said unit. into one memory, containing one of the identification numbers and code and address wirelessly via a handheld loader and one of the pads to load the box identifier; and a given ISB powered via a given ISB. The load is identified through one of said selectors and set to be a load identifier stored in a given memory, and one of the optical ports and RFID tags is configured to be a load identifier identified through one of said selectors and stored in a given memory, and one of said optical ports and RFID tags is configured to Accessed via a power outlet of the ISB with the wiring device configured to mate with a reader and attached to the ISB. one of an optical grid for propagating at least one of the optical signals through the POF, the grid comprising a low voltage for propagating electrical signals and an IR signal propagating within line of sight in the space; 32. The optical grid of claim 31, wherein the network includes propagation of signals consisting of the optical signal, the line-of-sight IR signal, the electrical signal, the RF signal, and combinations thereof through the POF. structured, integrated soft push to;
The controller is further programmed to exchange signals with groups consisting of video intercoms, shopping terminals, keypads, touchpads, handheld controllers, and combinations thereof. The optical signal and the electrical signal are bidirectionally convertible to interface a propagated optical signal with a propagated electrical signal, and the RF signal and the optical signal The RF is bidirectionally converted into an optical signal through the automation grid distributor and one of the ISBs to exchange signals corresponding to command and response signals of a given load. 33. The structured integrated light grid of claim 32. The operating command for a hybrid, combi or optically controlled switch operates at least one given load and includes data relating to the status of at least one of the current flowing through the at least one given load and the power consumption. 32. The structured integrated electrical grid of claim 31, responsive to provide to the controller and command converter: 35. The structured integrated electrical grid of claim 34, wherein the details of a given load powered by a given power supply device, one of the installation locations and a code and address combination are: The controller and a command converter for storing integrated control commands are randomly upgraded through the controller and enable short recall propagation of operational commands and responses through the grid and network, and a single Operating the predetermined function of the predetermined load at a predetermined location via an integrated command and a single integrated response. the specific load is responsive only to specific commands and responses, a given memory and a given memory of the controller and the command converter are updated to include the specific command and response, and the ISB is 36. The structured integrated electrical grid of claim 35, further configured via the controller to communicate the particular commands and responses with the particular loads. A diverse load powered via the ISB communicates with the diverse load via one of the RF signals, and a given memory and a given memory of the controller and the command converter communicate with the diverse load via one of the RF signals, and a response, the ISB being further configured to communicate, via the controller, each of the various commands and responses commensurate with each of the various loads. Structured integrated electrical grid described. The ISB(s) are horizontal boxes structured with the same size and capacity as the vertical boxes, and capable of carrying manual switches, hybrid switches, relays, power outlets, power sockets, IoT devices, AI devices, and 32. The structured integrated electrical grid of claim 31, wherein the integrated electrical grid is selected from the group consisting of combinations thereof and exceeds the newly introduced identical lateral and vertical size and capacity. said ISB includes on-off switching of a load powered via a given power outlet co-attached to said ISB for powering a load, attached to and directly connected to a hybrid switch; 40. The structured integrated electrical grid of claim 38, structured to turn on and off a loaded load. Said residential and commercial facilities include single-family houses, apartments in buildings, rooms and rooms in hotels, shops, restaurants, clubs, given areas of warehouses, offices, garages, workshops, classes and classes in schools. from one of the following: a library, a hospital room and rooms, at least one of a public building room and rooms, and at least one of a factory compartment and area. 32. The structured integrated electrical grid of claim 31 selected from the group consisting of: Comfortable touch and push means operated through a locked internal element and installed and/or configured to form a light blocking treatment on the generated controlled light, further comprising AC, DC The use of screws for cascading grids and power sockets, including switching and power supply, providing one or two plastic fiber optic lines for grounding, grounding, and immediate response to commands and actions. means for optical signal switching without the need for a light signal, they are shown as a plurality of hardened self-locking elements for a rigid fit, and/or
Push to lock or self-fit onto stripped power wires consisting of live AC (L), neutral (N), ground (G) and two plastic optical fibers (POF) for dual optical cascading One combined dual-line and intelligent support box used for POF segments and plugged into two separate or separated entries by finger press - dual access within ISB(s) be plugged in;
The dual cascaded POF links with the central processing unit (CPU) and also provides a link with the (Home Controller) - (Home Automation) - (HCHA), such as a personal vehicle or or enable two-way communication with nearby stores and similar surrounding devices using a reasonable 1MHz;
The ISBs can be configured to receive RF signals and/or IR commanded by (HCHA) by linking through a cascaded chain, or a single ISB further linked through a cascaded POF grid. All hybrid switches for switching on/off switching at least one light bulb installed in residential premises and/or commercial premises and/or public premises by directly communicating one of the signals. programmed to selectively support electrical wall box(s) and/or n electrical cabinet(s) and/or n lighting cabinet(s);
The plurality of ISBs are linked to the at least one home controller, command converter via at least one of a cascaded POF grid and at least one in space via wireless RF signals and/or IR signals. and/or further signaled by at least one of a light control light and/or a combination signal;
The ISB is self-configurable to a given set to load detailed status data combining operation and signals for reading the power consumed by each and all loads through at least one configuration selector. It is the communication circuit of a single or multiple ISBs (HCHA) or two-way signals that communicate with (HCHA) and command converters through one in the network and one in the air (HCHA). and the method comprises the following steps:
a. Loading said detailed data into a given identified ISB designed and configured containing data identified for allocation to said at least one memory device via said communication circuit;
b. a given identification number and at least one given code and address for identifying the installation location within said unit of each of said ISBs, either in a configuration selector and (HCHA); and/or configuring via either a handheld loader and/or a pad;
c. communication circuits and/or via at least one of the (HCHA) grid and network to a given memory and/or to the memory included in the (HCHA) and at least one of the command converter within said unit; recording details including the identified installation location; and
d. identifying, via said configuration selector and one of the identified loads, each load that is powered by one of said wiring devices, said (HCHA) or said command converter; stored in memory or through one of the power plugs having one of said handheld loader and an RFID tag mated to an optical port and a reciprocal optical port, and the RFID reader is connected to the power socket of said ISB. each of which is accessed via a power outlet of said wiring device attached to said wiring device. 41. The grid is a dual optical grid for propagating at least two of the optical signals through the POF in addition to an IR propagating signal that propagates line-of-sight in space. The method described in;
The network includes a propagating signal consisting of an optical signal through the POF, a line-of-sight IR signal, and an electrical RF signal in space, and combinations thereof, such as video intercom monitors, shopping terminals, (HCHA), home automation The grid is for communicating via push points for selecting a given controller selected from the group consisting of a distributor, keypad, touchpad controller, handheld controller, and combinations thereof. The optical signal and the electrical signal are bi-directionally converted through the command converter and one of the automation grid distributors to interface the propagated optical signal with an electrical signal, and the RF signal and the optical signal are is bidirectionally converted to interface the RF signal to an optical signal and the optical signal to an RF signal via at least one of the automation grid distributors, and the ISB 43. The method of claim 42, further comprising exchanging signals corresponding to command and response signals of a given load. said bidirectional signal comprises operational commands for switching on/off and operating at least one given load powered by at least one given electrical wiring device, said at least one given load 42. The method of claim 41, comprising a response for providing one of the (HCHAs) with at least one data regarding the state of the HCHA and one of current drawn and power consumed. said details of a given load powered by a given electrical wiring device having one of said installation locations, one of said codes or addresses, said operating commands and responses, and a given memory and said controller and commands; The integrated control commands are integrated into the control commands stored in at least one predetermined memory of the converter, and the integrated control commands are stored during the initial setup of the system, and upgraded from time to time via said controller, into a single integrated command. and the given function of the given load at a given location through a single integrated response, allowing short recall propagation of operational commands and responses through the grid and network. 45. The method of claim 44. A particular load powered through the ISB communicates through one of the RF signals in space and one of the optical signals by IR in line of sight with the optical port, load is responsive only to a particular command and response, a given memory and a given memory of said (HCHA)(s) are updated to contain said particular command and response, and said ISB is responsive to said particular command and response. 46. The method of claim 45, further configured via the controller to communicate specific commands and responses with the specific load. Diverse loads powered through the ISB(s) via one of the RF signals in space and via one of the optical signals from the optical port and IR in line of sight. communicating, the various loads reacting to the various commands and responses, a given memory of the controller and a memory of the command converter are updated to include the various commands and responses, and the ISB responds to the various commands and responses; 46. The method of claim 45, wherein the method is configured to communicate with each of the various loads and only the various commands and responses corresponding to each of the various loads. said ISBs to support said electrical wiring device selected from the group consisting of manual switches, light interrupts, light control and combination switches, hybrid switches, relays, power outlets, power sockets and combinations thereof; 42. The method of claim 41, comprising a restructured body to unify both horizontal and vertical versions into a single size, shape and capacity. said ISB(s) and a plug-in device to said ISB to turn on and off a load powered through a given selected power outlet co-attached to said ISB to power the load. Reconstructed to support power outlets and switches mounted by the same push-in for both horizontal and vertical implementation of one mounted manual switch and/or hybrid switch, including switching operations. 49. The method of claim 48. Said residential and commercial facilities include single-family houses, apartments in buildings, hotel rooms and one of several rooms, shops, restaurants, clubs, warehouses in a given area, offices, garages, workshops, school classes and one of a class, a library, a hospital room and at least one of a plurality of rooms, a public building and at least one of a plurality of rooms, and at least one of a location and an area within a factory 42. The touch method of claim 41, wherein the touch method is selected from the group consisting of: Structurally integrated comfort of soft push to light block and finger setting linked by its cascading POFs via an expanded POF grid by a cascading grid of ISBs At least one of the operating commands by (HCHA) is a push on the light cutoff or a push on the hybrid switch, and said light cutoff is pushed through the reinforced conductor that secures the power wire. To the home controller for expansion into multiple ISBs that are cascaded, the power wires consist of live AC power (L), neutral (N), and ground (G), and the plug-in For each of the units, it has a conductor that presses and secures the AC power supply to provide upgraded sensing;
Each ISB supports the calculated power delivered to n loads and also measures (HCHA) each power delivered by each of the n loads measured by a given current sensor. Report. Here, at least one optical interruption of the cascaded ISB(s) in the home is one cascade connection in the building, which is residential, public, commercial, factory, school, parking lot, museum, theater, airport and a second optical connection wire of a second cascaded ISB grid for communicating with the home surroundings by RF and/or IR between each facility and the home and vehicle and building surroundings (Figure 19-4A). 19B) for other buildings seeking automation.
Each of the plurality of ISBs loads detailed data related to each configured and installed ISB including a CPU, at least one of a configuration selector, and data related to configuring a home automation grid and wiring devices. a memory for, a circuit for operating and calculating the power consumed by each load via said wiring device, and at least one of said home controller and command converter via one of said home automation grid and network; , comprising a communication circuit for communicating at least one bidirectional signal;
Each ISB includes at least one sensor configured to power n powered devices (at least one), measured in advance or on an ad hoc basis, and at least 1 m/W. providing a current drain sensor measuring at 1 mS and measuring each power due to the load from 1 mW to 30 kW and set to cut-off (power cut-off) provided by the electrical wiring authority of a given country; and The configuration is via said at least one of a configuration selector or a given memory, and at least a controller and a command converter for recording and identifying each of said ISB(s) and their installation location within said unit. into one memory, containing one of the identification numbers and code and address wirelessly via a handheld loader and one of the pads to load the box identifier; and a given ISB powered via a given ISB. The load is identified through one of said selectors and set to be a load identifier stored in a given memory, and one of the optical ports and RFID tags is configured to be a load identifier identified through one of said selectors and stored in a given memory, and one of said optical ports and RFID tags is configured to Accessed via a power outlet of the ISB with the wiring device configured to mate with a reader and attached to the ISB. one of an optical grid for propagating at least one of the optical signals through the POF, the grid comprising a low voltage for propagating electrical signals and an IR signal propagating within line of sight in the space; 52. The optical grid of claim 51, wherein the network includes propagation of signals consisting of the optical signal, the line-of-sight IR signal, the electrical signal, the RF signal, and combinations thereof through the POF. structured, integrated soft push to;
The controller is further programmed to exchange signals with groups consisting of video intercoms, shopping terminals, keypads, touchpads, handheld controllers, and combinations thereof. The optical signal and the electrical signal are bidirectionally convertible to interface a propagated optical signal with a propagated electrical signal, and the RF signal and the optical signal The RF is bidirectionally converted into an optical signal through the automation grid distributor and one of the ISBs to exchange signals corresponding to command and response signals of a given load. 53. The structured integrated light grid of claim 52. The operating command for a hybrid, combi or optically controlled switch operates at least one given load and includes data relating to the status of at least one of the current flowing through the at least one given load and the power consumption. 52. The structured integrated electrical grid of claim 51, responsive to provide to the controller and command converter. 55. The structured integrated electrical grid of claim 54, wherein the details of a given load powered by a given power supply device, one of the installation locations and a code and address combination are: The controller and a command converter for storing integrated control commands are randomly upgraded through the controller and enable short recall propagation of operational commands and responses through the grid and network, and a single Operating the predetermined function of the predetermined load at a predetermined location via an integrated command and a single integrated response. the specific load is responsive only to specific commands and responses, a given memory and a given memory of the controller and the command converter are updated to include the specific command and response, and the ISB is 56. The structured integrated electrical grid of claim 55, further configured via the controller to communicate the particular commands and responses with the particular loads. A diverse load powered via the ISB communicates with the diverse load via one of the RF signals, and a given memory and a given memory of the controller and the command converter communicate with the diverse load via one of the RF signals, and a response, and the ISB is further configured to communicate, via the controller, each of the various commands and responses commensurate with each of the various loads. Structured integrated electrical grid described. The ISB(s) are horizontal boxes structured with the same size and capacity as the vertical boxes, and capable of carrying manual switches, hybrid switches, relays, power outlets, power sockets, IoT devices, AI devices, and 52. The structured integrated electrical grid of claim 51, wherein the structured integrated electrical grid is selected from the group consisting of combinations thereof and exceeds the newly introduced identical lateral and vertical size and capacity. said ISB includes on-off switching of a load powered via a given power outlet co-attached to said ISB for powering a load, attached to and directly connected to a hybrid switch; 59. The structured integrated electrical grid of claim 58, wherein the structured integrated electrical grid is structured to turn on and off a loaded load. Said residential and commercial facilities include single-family houses, apartments in buildings, rooms and rooms in hotels, shops, restaurants, clubs, given areas of warehouses, offices, garages, workshops, classes and classes in schools. from one of the following: a library, a hospital room and rooms, at least one of a public building room and rooms, and at least one of a factory compartment and area. 52. The structured integrated electrical grid of claim 51 selected from the group consisting of: