TWI632831B - On line free setting method, led security light, security light control device and led security light control device thereof - Google Patents

Abstract

An illumination control system using a software-based application for online setting of various operational parameters of a security light, including manual operation timer setting, detection range setting of a mobile sensor, sense of being moved The illumination duration setting triggered by the detector, and the illumination intensity and the illumination color temperature setting for various illumination modes. This technology allows the user to set an operating parameter within the maximum range of the design circuit. The design circuit is based on a line calculation and is designed and loaded in a smart phone according to his or her lifestyle. Application operation. The technology of the present invention is applied to a single-stage protection lamp, a two-stage protection lamp or a multi-step/life style protection lamp, and these protection lamps can be selected as an illumination source such as an LED load, an incandescent lamp load or any Other energized luminescent materials.

Description

Online free setting method and LED protection lamp and protection lamp control device therewith And LED protection light control device

The invention relates to a lighting device, in particular to an LED protection lamp, a protection lamp control device and an LED protection lamp with a mobile sensor.

Various types of light sources such as incandescent lamps, fluorescent lamps, halogen lamps, and light-emitting diodes are existing lighting devices. Outdoor lighting devices usually use a photoresistor to automatically activate the light source of the luminaire, called Photo-Control Mode (PC mode). In the light control mode, the timer is used to control the light source after a fixed period of time. The illumination of the luminaire is extinguished or switched to a lower brightness, called the Power-Saving Mode (PS mode). In the energy-saving mode, the motion detector is often used. When the person is detected to be close to the luminaire, the luminaire is activated. Brightly illuminate for a short time, then return to energy saving mode. Whether it is to automatically start the illumination by detecting the brightness of the backlight, the timing is fully bright and the brightness is controlled from full dark or lower power by detecting the action of the person, or the control of the brightness is adjusted, often using complicated circuit technology. Especially in the driving of light-emitting diodes, it still belongs to the technology of complex and high production cost.

The present invention provides an online free setting method based on a mobile device, such as a smart phone, for setting operating parameters of a lighting device, including: a user interface application, including at least one free setting algorithm, at least one free setting Calculus The method is preloaded in a mobile device to convert a user's setting decision into at least one operational variable of an operational parameter of the illumination device, wherein the user interface application is operable and at the touch of the mobile device Touching the screen panel; when the user interface application is triggered or terminated by at least one setting decision, the user interface application controls to transmit at least one wireless command signal to the light emitting device via the mobile device, and at least one wireless command signal carries a message of the operational variable, wherein the operational variable is an operational parameter for processing the illumination device; and corresponding to the user interface application of the mobile device, the illumination device includes a microprocessor designed to have at least one program for processing a variable, and an operating parameter of the illuminating device; wherein the value of the operating parameter is stored in a memory of the microprocessor for performance repeat performance, wherein a new operational variable will replace the set value of the operating parameter, new The operational variables are generated by a user selection process; wherein the operational parameters are used to control the lighting fixture A plurality of light emitting characteristics of at least one of a plurality of light transmitted through the light emission characteristics sensor or a movement sensor implemented, which includes a timer setting, the light emission intensity set, color temperature setting or sensing sensitivity setting.

The invention provides an LED protection lamp, comprising: an illumination unit, a load and power control unit, a photo sensor, a mobile sensor, a power supply unit and an external control unit. The external control unit is electrically connected to the load and the power control unit; wherein the light emitting unit comprises an LED light; wherein the load and power control unit comprises a microprocessor, a light sensor and a motion sensor, respectively electrically connected to the micro processing The microprocessor is further electrically connected to a controllable semiconductor switch, wherein the controllable semiconductor switch is electrically connected between a power source and an LED lamp of the light emitting unit, wherein the microprocessor outputs a control signal to control Controlling the conductivity of the semiconductor switch, the conduction rate refers to transmitting different average electric power to drive the LED lamp to perform various illumination modes, which are generated according to control signals from the photo sensor or the mobile sensor, when the light is generated When the ambient brightness sensed by the sensor is lower than a first preset value, the mobile sensor is turned on, and the load and power control unit simultaneously manages the light emitting unit to perform a first-order brightness mode; when the light sense The ambient brightness sensed by the detector is higher than When a second preset value is used, the light emitting unit and the motion sensor are both turned off by the load and power control unit; when the mobile sensor senses a mobile intrusion, the load and power control unit manage to increase the average electric power, and the average The electric power is transmitted to the light emitting unit to perform a second-order brightness mode for a predetermined duration, after which the light-emitting unit resumes performing the first-order brightness mode, wherein the first-order brightness mode and the second-order brightness mode respectively have different illuminations Intensity, wherein the illumination intensity of the second-order luminance mode is higher than the illumination intensity of the first-order luminance mode; wherein the external control unit includes a wireless receiver, and the wireless receiver is electrically connected to the microprocessor to receive and decode at least one wireless The signal becomes an operation variable, and the microprocessor operates the software to read and decode the operation variables. The software code of the microprocessor further includes at least one subroutine for processing the operation variable and adjusting a corresponding control signal. Corresponding control signals are based on operational variables received from the wireless receiver to perform at least one operational parameter, The middle operation variable represents a setting decision of a range operation rate, and the range operation rate is used for each function category of the operation parameters of the LED protection lamp, and is set by the user through an application preloaded on a mobile device, wherein the operation The parameter is for controlling at least one illuminating characteristic of the illuminating device.

The invention provides a security light control device, comprising: a load and power control unit, a light sensor, a mobile sensor, a power supply unit and an external control unit. The control light control device is electrically connected to a light-emitting load, wherein the load and power control unit comprises a controller operating in a software code, and the controller is electrically connected to the light sensor and the mobile sensor respectively, wherein the controller is more electrically Connected to a controllable semiconductor switch, wherein the controllable semiconductor switch is electrically connected between the light-emitting load and a power source, wherein the controller outputs a control signal to control the conduction rate of the controllable semiconductor switch, and the conduction rate refers to transmission Different average electric powers are used to drive the illuminating load to generate a plurality of illumination modes, which are generated according to control signals from the photo sensor or the mobile sensor, when the ambient brightness sensed by the photo sensor is lower than one At the first preset value, the motion sensor is turned on, and the load and power control unit simultaneously manages the light-emitting load to perform a first-order brightness mode when the light sensor senses the ring When the ambient brightness is higher than a second preset value, the mobile sensor and the lighting load are both turned off by the load and power control unit. When the mobile sensor senses a mobile intrusion, the load and power control unit manage to increase The average electric power, the average electric power is transmitted to the illuminating load to generate a second-order brightness mode for a predetermined duration, after which the illuminating load returns to the first-order brightness mode, wherein the first-order brightness mode and the second-order brightness mode Each has a different luminous intensity, wherein the luminous intensity of the second-order luminance mode is higher than the luminous intensity of the first-order luminance mode; wherein the external control unit includes a wireless receiver, and the wireless receiver is electrically connected to the controller to receive and decode the wireless The command becomes at least one operation variable of an operation parameter, and the operation parameter is used to operate the security light control device, wherein the software code of the controller further comprises at least one subroutine for processing the operation variable received from the wireless receiver, The operation variable is set by the user through an application, and the application is installed on a mobile device. At least one operating parameter for controlling Baofang light emission characteristic control device.

The invention provides a security light control device, comprising: a load and power control unit, a light sensor, a mobile sensor, a power supply unit and an external control unit. The control light control device is electrically connected to a light-emitting load, wherein the load and power control unit comprises a controller operating with a software code, wherein the controller is electrically connected to the controllable semiconductor switch, wherein the controllable semiconductor switch is electrically connected Between the illuminating load and a power source, wherein the controller outputs a control signal to control a conduction rate of the controllable semiconductor switch, and the conduction rate refers to transmitting different electric power to drive the illuminating load to generate different illumination modes, and the illumination modes Generating according to a control signal from a photo sensor or a mobile sensor; when the ambient brightness sensed by the photo sensor is lower than a first preset value, the mobile sensor is loaded and the power control unit Turning on, and the illuminating load is maintained in a closed state to perform a first-order brightness mode. When the ambient brightness sensed by the photo sensor is higher than a second preset value, the load and power control unit switches the moving sensor to be turned off. When the mobile sensor senses a mobile intrusion, the load and power control unit instantly turns on the lighting load to perform a high-order brightness mode. Continuing a predetermined short duration, after the lighting load to restore the closed state; the The medium-to-external control unit includes a wireless receiver, the wireless receiver is electrically connected to the controller to receive and decode the wireless command to become at least one operational variable of the operating parameter, and the operating parameter is used to operate the security light control device, wherein the controller The software code further includes at least one subroutine for calculating and setting an operation variable received from the wireless receiver, wherein the operation variable indicates a setting decision made by the user, and the operation variable is set by the user through an application, the application program Mounted to a mobile device, wherein operating parameters are used to control at least one illuminating characteristic of the illuminating device.

The invention provides an LED protection lamp control device, comprising: a load and power control unit, a light sensor, a power supply unit and an external control unit. The external control unit is electrically connected to the load and the power control unit; wherein the LED protection lamp control device is electrically connected to an illumination load, wherein the load and power control unit comprises a controller operating in a software code, wherein the controller is electrically connected and controllable a semiconductor switch, wherein the controllable semiconductor switch is electrically connected between a power source and a light-emitting load, wherein the controller outputs a control signal to control a conduction rate of the controllable semiconductor switch, and the conduction rate refers to transmitting a different average The electric power generates different illumination modes by driving the illumination load, and the illumination modes are generated according to the control signal from the photo sensor; when the ambient brightness sensed by the photo sensor is lower than a first preset value, the illumination The load is turned on by the load and power control unit to generate a first-order brightness mode for a first preset duration, after which the illumination load is switched to a second-order brightness mode, when the light sensor senses the environment When the brightness is higher than a second preset value, the light-emitting load is turned off by the load and the power control unit; wherein the external control unit is a wireless connection The wireless receiver is electrically connected to the controller to receive and decode the wireless command to become an operational variable, wherein the software code of the controller further includes at least one subroutine for processing the operation variable, wherein the operation variable indicates one of the operations The setting determines that the operation variable is set by the user through an application, and the application is installed on a mobile device, wherein the operating parameter is used to control at least one illuminating characteristic of the illuminating device.

The invention provides an online free setting method for setting operating parameters of a ceiling fan having a lamp set, comprising: a user interface application including at least one freedom Setting an algorithm, at least one freely set algorithm preloading a mobile device to convert a user's setting to determine at least one operational variable of an operating parameter of the ceiling fan of the light set, wherein the user interface application is Operatively, on a touch screen panel of the mobile device; when the user interface application is triggered or terminated by at least one setting decision, the user interface application controls to transmit at least one wireless command signal via the mobile device a ceiling fan having a lamp set, at least one wireless command signal carrying a message of an operation variable, wherein the operation variable is an operation parameter for processing or setting a ceiling fan having a lamp set; a microprocessor of the illumination device is designed to have At least one program for processing operational variables and operating parameters of a ceiling fan having a light sleeve set; wherein the value of the operational parameter is stored in a memory of the microprocessor for performance repeat performance, wherein a new one The operating variable will replace the set value of the operating parameter, and the new operating variable is generated by the user selection process; Parameters for controlling the fan having a plurality of light emission of the kit and at least one of electrical characteristics, electrical characteristics and includes a plurality of light emitting timer setting, speed setting of the fan, the fan rotation direction setting, and the light emission intensity setting color temperature setting.

In order to further understand the technology, method and effect of the present invention in order to achieve the intended purpose, reference should be made to the detailed description and drawings of the present invention. The drawings and the annexed drawings are to be considered as illustrative and not restrictive.

100, 500‧‧‧ security lights

110, 510‧‧‧Power supply unit

120, 520‧‧‧Light sensor

130, 530‧‧‧ mobile sensors

140, 540‧‧‧Load and power control unit

150, 550‧‧‧Lighting unit

160‧‧‧Time setting unit

170‧‧‧External Control Unit

590‧‧‧Wireless Receiver

600‧‧‧ mobile device

601‧‧‧Mobile device application

603‧‧‧Application subroutine

605‧‧‧Free setting algorithm

607‧‧‧transmitter

609‧‧‧Wireless Directive

5‧‧‧ fingers

71, 72‧‧‧ Free setting of operating factors

73, 74‧‧‧ indicator

75‧‧‧Virtual orbit

700‧‧‧User interface

701‧‧‧Manual operation

701A, 701B‧‧‧ sub-blocks

703‧‧‧Mobile delay time

705, 775 ‧ ‧ sensitivity

707‧‧‧ Brightness adjustment

709‧‧‧Color temperature setting

770‧‧ User Interface Application

771‧‧‧Manual operation mode

773‧‧‧Mobile delay time mode

777A‧‧‧High-order brightness

777B‧‧‧low-order brightness

990‧‧‧User Interface Application

991‧‧‧Manual operation

993‧‧‧ speed

995‧‧‧ brightness

997‧‧‧Color temperature

S801~S831‧‧‧Steps

S901~S931‧‧‧Steps

FIG. 1 is a schematic diagram of an LED protection lamp according to an embodiment of the present invention.

2 is a schematic diagram of a mobile device and an LED protection lamp according to another embodiment of the present invention.

FIG. 3A is a schematic diagram of a mobile device loading an application according to another embodiment of the present invention.

FIG. 3B is a schematic diagram of an LED protection lamp for loading an application according to another embodiment of the present invention.

4 is a schematic diagram of a user interface application according to another embodiment of the present invention.

4A is a schematic diagram of a user interface of a free time setting algorithm of a time length according to another embodiment of the present invention.

4B is a schematic diagram of a user interface of a free time setting algorithm for clock time according to another embodiment of the present invention.

4C is a schematic diagram of a user interface of a free-set algorithm for mobile delay time according to another embodiment of the present invention.

4D is a schematic diagram of a user interface of a free-set algorithm for sensing distance according to another embodiment of the present invention.

4E is a schematic diagram of a user interface of a free-form algorithm of a high-order luminance mode according to another embodiment of the present invention.

4F is a schematic diagram of a user interface of a free-form algorithm of a low-order luminance mode according to another embodiment of the present invention.

4G is a schematic diagram of a user interface of a color temperature free setting algorithm according to another embodiment of the present invention.

FIG. 5A is a flowchart of a method for setting an online freely according to another embodiment of the present invention.

FIG. 5B is a flowchart of a method for setting an online freely according to another embodiment of the present invention.

FIG. 6 is a schematic diagram of a user interface application according to another embodiment of the present invention.

6A is a schematic diagram of a user interface of a free-set algorithm for moving delay time according to another embodiment of the present invention.

6B is a schematic diagram of a user interface of a free-form algorithm of a high-order luminance mode according to another embodiment of the present invention.

FIG. 7A is a flowchart of a method for setting an online freely according to another embodiment of the present invention.

FIG. 7B is a flowchart of a method for setting an online freely according to another embodiment of the present invention.

FIG. 8 is a schematic diagram of a user interface application according to another embodiment of the present invention.

In the following, detailed description will be given by way of illustration of various exemplary embodiments of the invention. The invention is described. However, the inventive concept may be embodied in many different forms and should not be construed as being limited to the illustrative embodiments set forth herein. In addition, the same reference numerals may be used in the drawings to indicate similar elements.

The invention can be applied to a general illuminating device, a first-order brightness protection lamp, a second-order brightness protection lamp or a multi-level brightness/lifestyle protection lamp, and the illuminating load can be a non-linear illuminating load, such as a light-emitting diode. (LED) lamp; or a linear load such as a halogen lamp or other electrically energetic luminescent material.

Generally, a security light 100 (such as a light-emitting device) includes a power supply unit 110, a light sensor 120, a motion sensor 130, a load and power control unit 140, and a The light emitting unit 150, a time setting unit 160 and an external control unit 170. The load and power control unit 140 can be implemented by a controller circuit that includes a programmable device, such as a microprocessor, having the operation of a software code. In practice, the load and power control unit 140 performs various modes of operation of the security light 100 based on the sensed signals from the light sensor 120 or the motion sensor 130. The time setting unit 160 and the external control unit 170 are both used to adjust or set the operating parameters of the load and power control unit 140, and are used to perform various operating modes. Conventional techniques, for example, use a variety of push buttons and rotating knobs to form the external control unit 170, which is inconvenient to set or adjust the operational parameters of the security light. This embodiment develops user friendly techniques, such as wireless remote control techniques, to facilitate setting various operational parameters of the security light 100.

Conventional wireless remote control technology has been used for a long time and is used in electrical equipment operations, such as televisions, air conditioners, ceiling fans with lighting sets or lighting projects. The advantage of using wireless remote control technology is that it can easily control various operating functions of electrical equipment. The electrical equipment is placed at a high place or at a distance, so that there is no need to climb stairs, overlook the window, come down from the roof, or engage in other inconveniences. activity.

An application of wireless technology to remotely correct or set operational parameters of a security light system is already disclosed. For example, U.S. Patent No. 7,880,394 B2 discloses a technique for connecting an external memory to a controller for storing each type of The database of operating parameters is such that, based on the wireless command, the controller simply executes a look-up table procedure and selects parameters from the table to execute the selected operating parameters. The selection of each operating parameter is limited to a database that is pre-installed in the external memory.

In view of the commonly used mobile devices, such as smart phones, a special function application (APP) can be preloaded for freely setting the operating parameters of the security light system, thereby different from USPN 7,880,394. B2's patented technology provides a more flexible, convenient and efficient setting of technology.

Referring to FIG. 2 of an embodiment of the present invention, in order to implement a free setting technology based on the mobile device APP, the external control unit of the security light 500 is designed to include a wireless receiver 590, thereby receiving wireless from the mobile device 600. The instructions thereby adjust and set various operational functions of the security light 500. The security lamp 500 has a structure similar to that of FIG. 1, except for the integrated time setting unit 160 and the external control unit 170 and is generally indicated as a wireless receiver 590, and other circuit components such as a power supply unit 510, a light sensor 520, The motion sensor 530, the load and power control unit 540, and the illumination unit 550 remain unchanged. The wireless receiver 590 can be used as a wireless platform for performing a variety of external control functions such that the tedious work of manual setting on the security light panel can be eliminated. The security light 500 is based on the wireless receiver 590. The wireless platform has a wireless setting technology, so as to operate together with the software of the application APP pre-downloaded and installed on the mobile device 600, thereby realizing remote adjustment or correction of the control signal. Various modes of operation of the security light 500 are performed. The mobile device 600 is provided with an application APP for freely setting the operating parameters of the security light 500. The mobile device 600 is implemented by a smart phone, a tablet, a PDA, a notebook computer or a remote controller. This embodiment is based on software technology to use an application APP to freely set various operational parameters of the security light 500 on the operational line. Based on the above techniques, the application enables the user to arbitrarily select any value of the corresponding operational parameter. The operational parameters are, for example, the value of the movement delay time, the value of the sensitivity for the light sensor 520 or the motion sensor 530, the value of the brightness or the correlation mode of the various time calculations, the associated illumination intensity setting, or the distance setting of the associated mode. . operating The parameters are in a design category of the operational function and have a maximum range.

This embodiment discloses an online free setting method, which causes a user to set an "arbitrary value" of an operation parameter in each function class, and the setting of "arbitrary value" basically excludes the use of a conventional remote control technology. Conventional remote control techniques use the "pick and play" method to modify the operating parameters for the lamp in an alternating manner, as disclosed in the prior art USPN 7,880,394 B2; one of the external memories is designed to be stored The preset data of the plurality of values of the limited operating parameters, and the controller checks the form according to the wireless command that the user presses to play, and picks the indication data from the form of the memory to perform the operation. This "pick and play" technique uses a look-up table that is relatively simple and straightforward, but uses large amounts of memory.

The online free setting method of this embodiment on the other hand requires a more complicated technical implementation. Since the free setting may cause a large change in the user's instructions, it is not feasible or inefficient to use a larger capacity memory to store a larger database for free setting. A better way to achieve a free set range is to use an algorithm to instantly calculate the user's freely set parameters online. In other words, this embodiment is a "compute and play" method and does not require external memory and the "select and play" method as disclosed in USPN 7,880,394B2.

Referring to FIG. 3A, the mobile device 600 generally includes a processor, a memory, and a transmitter. An application based on a freely set algorithm is a memory that is pre-downloaded and installed on the mobile device. For example, when the user wants to adjust the brightness of the security light 500, the user uses the mobile device 600 with the application to transmit the wireless command 609 through the transmitter 607. The user opens the mobile device application 601, which can be understood as a user interface application, and thereby selects one of a plurality of available function blocks from the user interface. The function block selected by the application will call the corresponding application's subprogram 603 to display a freely set algorithm 605 on the screen of the mobile device 600. The free set algorithm 605 includes a free set operation factor, a virtual track coupled with a free set operating factor and an indication of the display range operating rate Symbol to provide instantaneous information on the range of operating rates of the range. The free set algorithm 605 allows the user to freely set the operating factor through finger swipe and select a range operating rate along the virtual track. The virtual track has an indicator of the display range operating rate to assist in the operation.

The user interface application 601 having the freely set algorithm 605 transmits a wireless command signal 609 through the transmitter 607 when a desired range operation rate of a corresponding operational parameter of the security light 500 is determined by the user. The anti-light 500, the wireless command signal 609 carries an encoded message having a selected range operating rate, and the selected range operating rate is treated as an operational variable for a corresponding operational parameter. Transmitter 607 of mobile device 600 transmits the above command and is received by wireless receiver 590 of security light 500.

Briefly, the user interface application 601 is installed on the mobile device 600 and converts a user's settings to determine an operational variable that becomes an operational parameter, wherein the operational variable is the range operational rate. The mobile device 600 wirelessly transmits a wireless command 609 having an operational variable to the security light 500, and the corresponding program installed on the security light 500 is triggered to use the value of the operational variable. The security light 500 produces a corresponding illumination characteristic output based on the selected operational variable of the corresponding operational parameter.

Please refer to FIG. 3B , wherein the security lamp 500 includes a wireless receiver 590 , a programmable control circuit or a microprocessor 540 , an illumination unit 550 , a light sensor 520 , and a motion sensor 530 . The microprocessor 540 is installed with at least one corresponding program corresponding to the freely set algorithm of the user interface application 601 installed in the mobile device 600. When the security light 500 receives a wireless command 609 through the wireless receiver 590, a corresponding program is triggered in accordance with the wireless command 609 to perform an online free setting of the operational parameters.

The freely set algorithm can be viewed as a range of scales simulating an operational parameter to facilitate a user operating a range of operating parameters for setting an operating parameter of an illumination device or an electrical device. This method is used to simulate the maximum range of operational functions of an illumination device or an electrical device and allows the user to select a range of operational parameters on the simulator. Operating rate. The present invention discloses two types of range scale simulators to implement a freely set algorithm; the first type range scale simulator is a virtual track coupled to a freely set operation factor, wherein the range operation rate of the operation parameters is located in the virtual The rest position on the track is determined by the rest position of the operating factor. The second type of range scale simulator is a virtual button that incorporates a range of free running subroutines, wherein the range operation rate is the length of time that a user continuously touches the virtual button and is compared to the length of the half cycle of the free running cycle. Come to choose.

Please refer to FIG. 4 to illustrate the above application APP based on the free setting technology. FIG. 4 illustrates an embodiment of the present invention, which is an image 700 of a touch screen displayed on a mobile device, and a visual free setting algorithm for simulating the user interface application 601. When the freely set user interface application is launched, the freely set algorithm is implemented by visual elements, including a group of icons on the display screen of the mobile device. Basically, a security light is designed to operate a variety of illumination modes, including manual operation 701, motion sensing related settings, such as motion delay time 703 and sensitivity 705, brightness adjustment 707, and color temperature setting 709. The icon shown in FIG. 4 represents a freely set algorithm including visual elements such as a freely set operating factor 71, a virtual track 75, and a digit indicator 73 to facilitate the user to set operational parameters of the security light. The display image of Fig. 4 is for convenience of explaining the free setting of the embodiment, and is not limited to the embodiment. In addition to the visualization implementation of FIG. 4, the freely set algorithm is, for example, a voice control means instead of touching the visual icon to listen to the user's voice to perform free setting. This embodiment does not limit the aspect of the user interface application.

Referring to function block 701, FIG. 3A and FIG. 3B of FIG. 4, the present invention discloses a manual operation setting method with a manual operation free setting algorithm. The manual operation settings include a test mode, an automatic mode, and a custom setting mode. When operating in the test mode, the microprocessor 540 operates to trigger a subroutine to disable the light sensor 520 such that the motion sensor 530 can operate during the day and the user can detect the motion sensor 530. The function and the decision setting of each operation parameter are released. When operating in automatic mode, the application operates to trigger a subroutine of a preset range of operating rates In the form of a wireless transmission to the security light 500, the subroutine of the preset range operating rate is suitable for programming all operating parameters of the application. Thereafter, the microprocessor 540 operates to calculate and adjust the corresponding control signals such that the security light 500 operates each of the operational parameters in accordance with each predetermined range operating rate R. For example, when operating in a custom setting mode, the application operates to trigger a subroutine to execute a programming timer (subblock 701A) and to temporarily disable the motion sensor 530 and allow the user to follow the virtual The track 75 slides freely to set an operating factor 71, simulating a time length counter. The full length of the virtual track 75 is equal to the maximum length of the programming timer, and the programming timer is actually designed to be 12 hours. Therefore, when a user's finger 5 stops sliding and stops at a position of 1/3 of the full length of the virtual track 75, for example, the indication symbol 73 of the range operation rate R is simultaneously displayed for a length of time of 4 hours, that is, when the light is sensed. When the 520 automatically turns on the security light 500, the selected length of time is to perform a constant illumination mode, starting from the twilight time. In addition to the fixed time length timer (sub-block 701A) for performing general illumination, the custom setting mode further provides an option to freely set a clock time timer (sub-block 701B), wherein the virtual track 75 is served as a clock time scale. When the user's finger 5 slides along the virtual track 75, the indication symbol 73 of the range operation rate R synchronously displays an instantaneous clock time for setting the reference, and the rest time when the user's finger 5 stops sliding, the clock time setting is Completion and decision, whereby the free setting application operating the custom set clock time is programmed to convert or convert a clock time to an equivalent time period setting, and the equivalent time period setting is used from the mobile device 600. The clock time is referenced, and the converted time period information is wirelessly transmitted to the security light 500 for online execution. For example, suppose the user sets 10 pm as the time point to convert the lighting mode from the timer mode to the mobile sensing mode at 4 pm, and the application calculates to convert the 10 pm clock time, which is equivalent to Equation 10. (pm)-4 (pm) = 6 (hours). When the security light 500 is automatically turned on at dusk, the application transmits a wireless command 609 to operate a 6-hour delay time. From the setting of 4pm, the microprocessor 540 thus set performs the time calculation. Cut from 6 hours after setting the moment to 4pm The warranty protection lamp 500 changes from the timer mode to the motion sensing mode. This conversion can also be accomplished by the microprocessor 540 within the security light 500, i.e., in place of the conversion of the application pre-installed within the mobile device 600. In such cases, the application only provides clock time input so that an algorithm within microprocessor 540 can perform the conversion. Furthermore, please refer to FIG. 4A, FIG. 4B and FIG. 4, which describe details of the self-setting setting parameters. 4A and 4B respectively provide a user interface of the free-form algorithm (sub-block 701A) of the length of time, and a user interface of the free-form algorithm (sub-block 701B) at clock time, how is the user interface performed? A schematic diagram of free setting. As shown in FIG. 4A, a time length timer is set at 4 hours. As shown in FIG. 4B, a clock time timer is set at 10:30 pm.

The embodiment further discloses a moving delay time setting method for generating high-order illumination via a motion sensor, the method having a moving delay time free setting algorithm. Referring to function block 703 of FIG. 4, when the mobile sensor 530 detects a mobile intrusion, the microprocessor 540 immediately turns on the security light 500 or increases the brightness of the security light 500, and cuts into a low-order brightness mode. The high-order brightness mode continues for a period of high-order brightness, which is defined as the movement delay time to provide a safety alert before returning to the off state or low-order brightness mode. In this embodiment, the virtual track 75 serves as a moving delay time scale, the length of which represents the maximum time length of the movement delay time, when a user finger 5 slides along the virtual track 75 to freely set the operation factor 71, a range operation rate R The indicator 73 synchronously displays the instantaneous value of the movement delay time to assist the user in making a setting decision. Assuming that the maximum time length is designed to be 20 minutes, a rest position is at the 5% position of the full length of the virtual track 75, that is, the indication symbol 73 of the range operation rate R represents the movement delay time of 1 minute, and the microprocessor 540 accordingly ranges the operation rate. R is multiplied by the control signal S(max) of the maximum movement delay time, S(new) = S(max) x R = 20 minutes x 5% = 1 minute, and is operated accordingly to perform a one minute movement delay time. Figure 4C, which corresponds to function block 703, is a freely set drawing diagram in which a user interface of the mobile delay time freely set algorithm can be operated. As shown in Figure 4C, it is a mobile delay time, set to 1 minute or maximum. 5% of the movement delay time.

The embodiment further includes a sensing sensitivity setting method, the method having a sensing distance free setting algorithm. Referring to function block 705 of FIG. 4, a user interface is illustrated, and the operating parameters of the sensing distance of the motion sensor 530 are freely set. The full length of the virtual track 75 represents the largest sensing distance. When the user's finger 5 slides along the virtual track 75 to freely set the operation factor 71, an indication symbol 73 of the range operation rate synchronously displays the instantaneous variation value of the sensing distance to help the user to make a setting decision on the sensing distance. Assuming that the maximum sensing distance for the mobile sensing circuit is designed to be 70 feet, when the user stops sliding and stops the freely set indicator 73 at the 30% position of the full length of the virtual track 75, the range operation rate The indicator 73 simultaneously displays the sensing distance of "70 feet x 30% = 21 feet", and the sensing distance of the motion sensor 530 is set to 21 feet. The application thus transmits a wireless command 609 having a value of 30% to the guard light 500, and the microprocessor 540 receives the wireless command 609 to operate to trigger a corresponding subroutine to proportionally adjust the voltage. The signal, thereby controlling the amplification intensity of the motion sensing signal, so the sensing distance of the security light 500 is set at 21 feet. Figure 4D of the corresponding function block 705 provides a freely set drawing diagram in which a user interface of the sensitivity distance freely set algorithm can be operated. As shown in FIG. 4D as a sensing distance, it is set at 35 feet or 1/2 of the maximum sensing range.

This embodiment further discloses a brightness setting method having a free setting algorithm of a luminance value. As shown in function block 707 of FIG. The brightness free setting algorithm includes a subroutine 707A for setting a high-order brightness mode, and another subroutine 707B for setting a low-order brightness mode. In the functional sub-block 707A for setting the high-order brightness mode, the length of the virtual track 75 represents an adjustable range of the brightness value, from a minimum starting point of 50% of the designed maximum brightness range to a maximum end point of 100%, or from The minimum operating value is 1000 lumens to a maximum operating value of 2000 lumens. When the user sets the operation factor 71 by sliding freely along the virtual track 75 of the range operation scale, from the minimum starting point to the maximum end point, the indication symbol 73 of the range operation rate changes synchronously. The value, from 50% to 100% or from 1000 lumens to 2000 lumens, helps the user to make a decision to stop setting based on the instantaneous percentage value or actual operational value displayed by the indicator 73 of the range operating rate.

In functional sub-block 707B for setting the low-order brightness mode, the length of the virtual track 75 represents an adjustable range of brightness values from a minimum starting point of 0% of the maximum range of design to a maximum end point of 50%. When the user slides along the virtual track 75 to freely set the operation factor 71, from the minimum starting point to the maximum end point, the range operation rate indicator 73 synchronously changes the percentage value from 0% to 50% or from 0 lumens to 1000 lumens. To help the user to make a decision to stop the setting based on the instantaneous operation percentage or the actual operation value displayed by the indication symbol 73 of the range operation rate. 4E and 4F correspond to sub-block 707A and sub-block 707B, respectively, and provide a user interface for the brightness free setting algorithm for the high-order brightness mode and the low-order brightness mode, which is a schematic diagram of how to perform a free setting operation. FIG. 4E illustrates a luminance value for a high-order luminance mode, which is set at a luminous output of 75% or 1500 lumens of the maximum luminance value. FIG. 4F illustrates a luminance value for a low-order luminance mode, which is set at a luminance output of 20% or 400 lumens of the maximum luminance value. Figure 4G corresponds to function block 709, which provides a user interface for the color temperature freely set algorithm, which is a schematic diagram of how to perform a free set operation. Figure 4G shows that a color temperature is set at 3000K.

The user interface freely set the algorithm thus set, when the user slides along the virtual track 75 to freely set the operation factor 71, the instantaneous range operation rate is synchronously displayed on the indication symbol 73 of the range operation rate, so the user can operate according to the range. The information provided by the indicator 73 of the rate is determined by immediately releasing a setting, and the numerical information of the indicator 73 displayed in the range operation rate may be a percentage of the maximum range or an absolute value of the operation parameter, for example, for sensing. The operational parameter of the distance, which is more meaningful to display the sensing distance of 21 feet or 35 feet instead of the sensing distance of 30% or 50%. Also, the operational parameters are related to the length of time, such as the motion sensor 530 triggering the conduction illumination duration or a manual mode of operation, wherein the motion sensor 530 is temporarily disabled and lasts for a longer duration, for this type of Operating parameters, use People prefer to know an absolute value, not a percentage value. In any case, it can be designed as a code that alternates between an operation percentage and an absolute value. The user can freely set the operation factor 71 with a single click or a double click, and the switch is as follows.

The user interface free setting algorithm thus set allows the user to slide the free setting operation factor 71 between a minimum starting point and a maximum end point on the virtual track 75 to determine a rest position for the free setting operation factor 71. Therefore, according to the range operation rate indicator 73, a range operation rate is determined; FIG. 4 is provided with a storage button located in the upper right corner of the application screen, and when the confirmation free setting is pressed, the "storage key" is pressed, and the application software is acted upon accordingly. The device 600 sends a wireless command signal 609, and the wireless command signal 609 carries a range operation rate message. The code is encoded according to the type of the operation parameter, and the message is transmitted through the wireless transmission means of the mobile device 600 (such as Wi-Fi, Bluetooth or RF) for transmission to the security light 500. For practical considerations, it is designed to have a range operation rate starting at the minimum of 0. For example, the movement delay time needs to have a minimum value, such as 5 seconds. Otherwise, when the movement delay time is set to 0, the motion sensor 530 will not perform its function, thereby confusing the user. The same considerations apply to the sensing distance setting, which starts at some minimum, like 2 feet. Otherwise, the motion sensor 530 will not perform its function when the sensing distance is set to zero. This means that the length portion starting from 0 is obscured or hidden, and there is no algorithm for the range operation rate "R" in the variation calculation, by dividing the length "P" of the rest position by the full length of the virtual track 75 "L", The rest position is calculated from 0 o'clock and is named

R=P/L

In addition, since the finger 5 has its smallest contact area, the contact between the user's finger 5 and the application touch screen is not a single point. It is practical to note that the length configuration of the virtual track 75 is a multiple of the minimum percentage increment. For example, assume that the minimum percentage increment is set to 5%, which means that a total of 20 partition intervals are split, with a range operation rate of 5% multiple at the abscissa of each partition interval. Therefore, the virtual track The length of the track of 75 gradually increases from 0%, 5%, 10%, 95%, to 100%. Therefore, when the user's finger 5 slides along the virtual track 75, the range operation rate displayed by the indication symbol 73 of the range operation rate changes in synchronization according to the sequence modes of 0, 5%, 95%, and 100%. Therefore, when the user stops the free setting operation factor 71 at a point of the virtual track 75, the stationary position is over a partition interval, and a corresponding range operation rate is equal to a certain multiple of 5% increment.

The user interface 700 of the application includes at least one slidable free setting operation factor 71. The free setting operation factor 71 is coupled to at least one virtual track 75 and at least one range operation rate indicator 73. The indicator symbol 73 is located in the free setting operation factor. Near 71, and used to display reference values instantaneously. The free set operating factor 71 can be slid along the virtual track 75 by the user's finger 5, which represents a range of circuit operating parameters that simulate a security light 500 with respect to the operational parameter category. For example, assuming that the sensing distance is referred to as an operating parameter, the full length "L" of the virtual track 75 represents the maximum sensing distance, is designed for the circuit of the protective lamp 500, and is used to operate the sensing distance. In this way, by sliding the free setting operation factor 71 along the virtual track 75, the sensing distance can be adjusted from a starting point of the minimum value to an end point of the maximum range. When the user stops sliding and stops the free setting operation factor 71, for example, at the intermediate point of the virtual track 75. The range operation rate is indicated as 50%, or 35 feet (assuming a maximum sensing distance of 70 feet). The range operation rate indicator 73 displays the range operation rate, designed at a screen position near the free setting operation factor 71, and when the slide is made, to provide the user with a value of the range update rate of the instantaneous update. The value displayed by the indicator 73 of the range operation rate may be a relative percentage information or an absolute value information attached to the designed operational parameters. The purpose of this embodiment is to help the user to make a decision based on the indication information to easily make a free decision. 4C and FIG. 4D illustrate a visual indication for providing absolute values, respectively, for setting a movement delay time and a sensing distance setting, so that the user of course sees the length information and the sensing distance information. This helps the user to slide, stop, and release the decision.

Corresponding to the freely set algorithm part of the mobile device 600, the security light 500 A corresponding software program is installed in the microprocessor 540 of the security light 500 to perform an operation parameter corresponding to the online free setting, and the input of the range operation rate R used is from the user interface application of the mobile device 600. A plurality of subroutines are designed to handle the corresponding operational parameters. Therefore, when the user interface application generates a wireless command 609, the wireless command 609 is received through the wireless receiver 590, and the microprocessor 540 operates to trigger a corresponding subroutine to interpret, calculate, and scale a relative voltage control signal. The value or time length control signal is used to control the corresponding operational parameters of the security light 500 to perform the value of the selected operational parameter. For each type of operational parameter, microprocessor 540 can read and interpret range operation rate R. In more detail, each subroutine of the various types of operating parameters is operated to multiply the maximum range value of the control signal S(max) by the range operating rate R to obtain a proportionally adjusted signal S(new)=S (max)x(R). The control signal S(max) can be a voltage control signal or a time length control signal. The new control signal S(new) is operated accordingly to vary the operating parameters. For example, assuming that the free set operation factor 71 is at the 60% position of the virtual track 75 for sensing an operational parameter of the distance class, the microprocessor 540 automatically calculates that the sensing distance is set to 42 feet (75 feet x). 60%), thereby correspondingly controlling the movement sensing circuit to proportionally adjust the voltage signal.

Referring to FIG. 5A, a flowchart is illustrated for a mobile device to perform the free-form algorithm of the present embodiment. In step S801, the user has to open a user interface application designed on the mobile device 600 with an online free setting method, for example, to turn on the operation of the free set algorithm. Thereafter, in step S803, the user selects a corresponding free-form algorithm, which is designed to set a specific operational parameter, for example, an operational parameter such as manual mode, motion delay time, sensitivity, and brightness. In step S805, the user slides along the virtual track 75 to freely set the operating factor 71 to adjust the operational variables of the selected operating parameter. In step S807, the application operates to calculate or convert the instantaneous sliding position of the user to become the range operation rate R, wherein the operation variable is the range operation rate R.

In step S809, the user observes the instantaneous value of the range operation rate R of the change, and displays On the indicator 73 of the range operation rate R. In step S811, the user decides an acceptable range operation rate R, and stops the free setting operation factor 71 at the decision time. In step S813, the user confirms the acceptance range operation rate R by pressing the storage key. Thereafter, in step S815, the application operates to wirelessly transmit the wireless command 609 with the selected range operation rate R to the security light 500.

Referring again to FIG. 5B, a flow chart is illustrated for the security light 500 to perform the free-form algorithm of the present embodiment. In step S821, the user interface application pre-installed on the mobile device 600 generates a wireless command 609 that is received and converted by the wireless receiver 590 of the security light 500 to become a signal-carrying message. Thereafter, in step S823, the microprocessor 540 of the security light 500 reads and interprets the message carrying the freely set signal number on the cable to derive a percentage value of the range operation rate R. At step S825, microprocessor 540 operates to trigger a corresponding subroutine of a designed operational parameter. In step S827, the subroutine operates to perform a calculation to control the maximum value stored by the signal S(max) multiplied by the percentage value received by the range operation rate R to obtain a new control signal S(new), named Is S(new)=S(max)x R. At step S829, the microprocessor 540 operates to apply the scaled control signal S(new) to manipulate the circuit corresponding to the operational parameters, so that the online free setting of the operational parameters is completed, as in step S831.

In summary, the user interface application is used for an online free setting operation to switch the user's setting decision to become the range operation rate, and the range operation rate is wirelessly transmitted to a remotely located security lamp 500. There are many ways to simulate the freely set algorithm of a mobile device. The first method discloses a virtual track method as shown in FIG. 4, wherein the user interface application with a freely set algorithm includes a free set operation factor 71, a virtual track 75 coupled with a free set operation factor, and a range operation rate. An indicator 73, wherein the free setting operation factor 71 is slid along the virtual track 75 by the user's finger 5, the virtual track 75 has an indication symbol 73 of the range operation rate, and the synchronous display range operation is performed when the sliding of the free setting operation factor is performed. The instantaneous value of the rate, wherein the value displayed by the indicator 73 is the most The percentage of operation of a large operating range, or the actual operating value of an operating parameter, wherein the full length of the virtual track 75 represents the maximum operating range of a simulated corresponding operating parameter, the operating parameter corresponding to a corresponding circuit, wherein the virtual track 75 It is divided into several small compartments, several small compartments represent different values of the range operation rate, and the sequence values are arranged to form the full length of the virtual track, wherein the range operation rate is determined by the rest position of the freely set operation factor, when the sliding stops The free setting operation factor is a compartment of a virtual track having a corresponding range operation rate. When a stop decision is issued, the user touches or presses the storage key, and accordingly the application transmits the mobile device via the mobile device. The wireless command signal is applied to the security light to perform illumination characteristics corresponding to the set operating parameters.

In addition to the above-described virtual track method as a first type of range scale simulator, the present invention also discloses a second type of range scale simulator using a virtual button method. Please refer to FIG. 6, which is an embodiment of the present invention. An image of a virtual button of the user interface application 770 of FIG. 6 is displayed on the screen of the mobile device. The user interface application 770 includes a plurality of freely set algorithms installed in the mobile device 600 for setting various operational parameters, including a manual operation mode 771, a mobile delay time mode 773, a sensitivity 775, a high-order brightness 777A, and a low-order brightness. At least one setting such as 777B.

Each free set algorithm is used for a corresponding operating parameter, including a free set operating factor 72, a free running subroutine (not shown), and an indication of the instantaneous range operating rate 74, wherein the freely set operating factor 72 A virtual button is designed on the touch screen panel of the mobile device 600. When the virtual button is continuously touched by the user's finger 5, the user interface application operates to trigger a free running subroutine, causing the range operation rate to be gradually increased, from a minimum value to a maximum value, and then from the maximum value to the minimum value. The value is to complete the complete cycle of a free-running movement, and the free-running movement has an area that can be viewed, determined, and released by the user. During a free running period, the instantaneous value of the range operating rate is simultaneously displayed on the indicator 74 of the range operating rate, wherein the value of the range operating rate may be an operation of the operating parameter. The ratio or an absolute operation value, in which the free-running movement is immediately stopped when the user's finger 5 is removed from the virtual button 72, the range operation rate is thus locked at the last moment of the free-running movement. The length of the half cycle of the free running movement represents the value of the maximum operating range of a corresponding operating parameter of a simulation, characterized by a corresponding circuit in which the length of time of each half cycle is divided into a plurality of time intervals, these times The interval represents different values of the range operation rate, and is arranged according to the numerical sequence. When the user's finger moves away from the virtual button, the range operation rate is determined at that time point, wherein the time point corresponds to a configured range operation rate. a time interval. When a setting decision is made, the user interface application transmits a wireless command signal to the security light via the mobile device to set the operational parameters.

Referring to FIG. 6A, FIG. 6B and FIG. 6, the images of the user interface application 770 are shown, respectively, a movement delay time setting 773 and a high-order brightness setting 777. When the user's finger 5 continuously touches the virtual button 72, the user interface application operates to trigger a free running subroutine to vary the cyclic range operating rate, from the maximum value to the minimum value, and then from the minimum value to the maximum value. It also has an area for the user to observe, decide and release actions. During a free running cycle, the instantaneous value of the varying range operating rate is simultaneously displayed on the indicator 74 of the range operating rate, for example, "5s" of the moving delay time in FIG. 6A, and the higher order brightness in FIG. 6B. "75%". Assuming that the user selects a value at a point in time and releases his finger from the virtual button 72, the indicator 74 locks at a value of the range operation rate that the user desires. When the setting is completed, the user touches or presses the "storage key" to transmit the wireless command signal to the security light via the mobile device, thereby setting the corresponding operational parameter. Basically, the benefit of running a free-running subroutine is that the virtual key method of Figure 6 represents the use of fewer icons on implementing a free-form algorithm than the virtual track method represented by Figure 4.

7A and 7B show the operation flow of the online free setting application, similar to FIG. 5A and FIG. 5B. The difference between FIG. 5A and FIG. 7A is a method of realizing the free set range operation rate. FIG. 5A illustrates a virtual track 75 that passes through the scale of operation along the range. A virtual track method of freely setting the operating factor 71 is slid, and when the sliding is performed, there is an auxiliary indicator 73 to provide an instantaneous value of the range operating rate. The user can instantly select a stop location point to determine a desired range operation rate. 7A illustrates a virtual button method for continuously touching a virtual button 72 of a freely set operating factor to trigger a free running subroutine with an auxiliary indicator 74 to provide an instantaneous value of the varying range operating rate, using The user can immediately select a point in time to lock the free running range operating rate without touching the virtual button 72. In other words, the free setting method of FIG. 5A uses a distance length simulation method to derive the range operation rate; the free setting method of FIG. 7A uses a time length simulation method to derive the range operation rate. The instantaneous value of the range operation rate may be an operation percentage or an actual operation value; in a short time interval, a simple touch or a double touch (double touches) on the freely set operation factor to alternately switch An operation percentage or an absolute value for the range operation rate. So configured, in step S901, the user opens the application on the touch panel of the smart phone to open the application freely. In step S903, the user selects a corresponding free-form algorithm corresponding to an operation parameter. In step S907, the user touches or presses the free setting operation factor to trigger a free running subroutine. In step S909, the free running subroutine causes the indication of the range operation rate to synchronously display the instantaneous value of the gradually varying range operation rate, from the minimum value to the maximum value, and then from the maximum value to the minimum value, to complete an operation cycle. In step S911, the user observes the free running value of the fluctuation of the range operation rate. In step S913, the user decides to select a momentary value of the free running range operation rate. In step S915, the user removes his finger from the free setting operation factor to lock the instantaneous value of the range operation rate. In step S917, the user confirms that the lock value of the range operation rate is acceptable by pressing the storage key. In step S919, the application operates to transmit a wireless command of the message of the selected operating rate to the security light 500, and the operating rate is encoded corresponding to a corresponding operational parameter. As shown in Figure 7A, a user interface application is the first part of an online free application. The application is installed on a smart phone and can be operated on a smart phone. Touch the screen panel. Figure 7B is the second part of the online freely set application, which is installed on the microprocessor of the security light 500 to interpret, calculate and set operational parameters based on wireless commands from the smart phone.

As shown in FIG. 7B, the second part of the online free setting application starts in step S921, in which the receiver of the security light receives and converts the wireless command signal to be converted into a signal-carrying message. In step S923, the microprocessor reads and interprets the signal-carrying message to obtain a value of the range operation rate. In step S925, the microprocessor accordingly triggers a corresponding subroutine for processing the operation rate. In step S927, the application operates to multiply the range operation rate R by its maximum control signal S(max) to obtain a proportionally adjusted control signal S(new). In step S929, the microprocessor applies the proportionally adjusted control signal S(new) to the corresponding circuit. In step S931, an online setting of a corresponding operational parameter is completed.

In summary, the application of the present embodiment is based on an online free setting method for determining the operating parameters of the security light 500, thereby providing the user with a convenient method to set the optimal value of the operating parameters. When compared to conventional remote control techniques, this embodiment has the effect of cost savings for comparison of the following features.

This embodiment uses a "calculation and playback" technique to freely set operating parameters, wherein the conventional remote control technique uses the "select and play" method to modify the operating parameters. This "select and play" method requires an external memory to store all preset values of the operating parameters, and the controller performs "select and play" according to the wireless command. It only provides a restrictive choice, is limited by memory capacity, and increases the cost of installing memory. This embodiment provides a freely set operational parameter on the other hand through a computational algorithm. Do not use external memory, use external memory that stores a limited database in advance, or use external memory for the "select and play" method.

The freely set algorithm is an application software designed to improve the inconvenience of conventional hardware based on remote control technology. Conventional techniques such as USPN 7,880,394B2 (abbreviated as 394 conventional techniques) are older techniques than the present invention; 394 conventional techniques at the time of patent application clearly combine two existing available techniques. These two are now The storage technology, including the "select and play" method and remote control technology, has been applied to TV program selection, air conditioning control, ceiling fans and lamp sets control. Prior to the 394 prior art application, the user interface of the 394 prior art was a relatively old technique in which the remote control included a plurality of hardware, such as a button system for alternately setting third order values of various operational parameters (high, Medium and low values). It simply transmits the user's selection decision to the control circuit of the security light to perform the "select and play" function to alternately modify the operating parameters. The user interface of the present invention, on the other hand, provides more feature points than the 394 prior art.

The user interface application APP of the present invention can be freely downloaded to a smart phone. This represents convenience and cost savings. No additional memory is required, and a separate remote control is provided. Smart phones have powerful capabilities in terms of storage memory and computing power. When the conventional external memory is compared with the powerful memory capacity installed on the smart phone, the external memory of the 394 conventional technology can be ignored, and the smart phone is designed to store thousands of photos. A fraction of the memory capacity of a smart phone is several times that of the external memory of the 394 conventional technology, and does not require additional cost to use the smart phone capability that controls the illumination characteristics of the security light. In addition, smart phones have powerful computing and processing capabilities to connect to the previous lighting device to become highly intelligent with artificial intelligence and machine learning technology.

The user interface algorithm is designed to have friendly features, unlike the 394 conventional technique, which provides only high-order/intermediate/low-order operational choices to continuously press a button for the corresponding operational parameters. . The invention provides more choices of operating parameters in the memory capacity of the smart phone and in practice. Moreover, in the free setting process, the indicator symbol can provide a transient state of the range operation rate of the change, so that the user can easily select a certain value and release a desired setting decision.

When it becomes a program for a smart phone, it does not incur additional control costs. The remote control has troubles such as unclear placement and lack of power in the battery. Because the remote control is not used like the smart phone of interest, the smart phone is always used in your wallet or pocket. And the battery is often fully charged.

The user interface application is pre-installed on the mobile device, giving the light fixture the authority to use the powerful storage memory and computing power of the smart phone. Compared to the method taught by the prior art 394, the method installs an external memory in the luminaire to perform "selection and playback", which is an outdated technique. In order to use the powerful storage memory and computing power of the smart phone, the calculation of various operating parameters can be done by the application of the smart phone or by the program written by the microprocessor of the light fixture. In order to complete the calculation work in the smart phone, the generated operation variable is the operation parameter, and the microprocessor of the illuminating lamp completes the calculation work, and the generated operation variable is the range operation rate. In such embodiments, no external memory is required.

The simulated range scale disclosed herein is a friendly technique that allows the user to freely set an expected value of the operating parameters and has an indication of the auxiliary range operating rate. The 394 prior art does not have any friendly technique compared to this embodiment.

The more useful operational functions in this embodiment are designed to take full advantage of the advantages of the online free setting method; the preferred example is the manual mode of operation, which replaces the switching of the illumination mode from dusk to dawn. This embodiment instead provides an adjustable timer mode in which the user can set an arbitrary duration for operating the general illumination mode when the motion sensor 530 is disabled, the user simply following the range of the virtual track 75 The simulation scale, sliding freely sets an operating factor of 71 to determine the length of time desired for nighttime activities. Moreover, as the general illumination mode can be set to the clock time point, instead of the length of time, it is feasible to plan as such in the mobile device 600, and the mobile device 600 can provide a clock time input. Another embodiment is the illumination brightness value adjustment for various illumination modes, which are triggered by the light sensor 520 or the motion sensor 530, and different users adjust different illumination preferences according to their lifestyle. The online free setting method of the embodiment allows the user to select an arbitrary value of the luminance of the illumination, and freely sets the operation factor 71 by sliding along the range of the virtual track 75, respectively, from 50% to 100% of full brightness. High-order brightness mode and low-order brightness mode from 0% to 50%. When the low-order brightness is set to 0%, the protection lamp 500 is a single-stage protection lamp; when the other values are set, the protection lamp 500 is a two-stage protection lamp or multi-step A protective light with a life style.

Referring to Figure 8, an embodiment of the present invention is represented. Applications based on the above techniques can be extended to include additional functionality in which the security light 500 can be integrated into other electrical devices, for example, in an electric ceiling fan. It may also be a combined system in which the integrated ceiling fan and the security light 500 are integrated and implemented by the controller circuit of the modified load and power control unit 540. 8 is a visualized embodiment of a free-form algorithm of a user interface application 990 for a combined system including a security light and a ceiling fan, wherein the visual selection elements are fan, light, and custom settings, both designed Under the category of manual operation 991, the benefits of various operating parameters of the user selection and online setting of the protective lamp 500 and the ceiling fan are provided. For example, by operating the user interface application to control the clockwise or counterclockwise rotation of the ceiling fan, and to adjust the rate of rotation. Briefly, the operating parameters of the present embodiment are used to control at least one characteristic of various lighting and electrical characteristics of a ceiling fan having a lamp set, the at least one feature including a timer setting, a fan wind speed setting, and a fan rotation direction setting, and illumination. Strength setting and illuminating color temperature setting.

In summary, the various embodiments of the free-form algorithm are not intended to limit the scope of the invention. The above description of the illustrated embodiments is not intended to be exhaustive or to limit the embodiments. While the invention has been described with respect to the specific embodiments and the embodiments of the present invention, it will be understood by those skilled in the art that various equivalent modifications can be made without departing from the spirit and scope of the invention. These and other modifications can be made to the embodiments in light of the above detailed description. In general, the terms used in the following claims should not be construed as limiting the scope of the claims to the specific embodiments disclosed in the specification and claims, but should be construed as including all possible embodiments. And the full scope of the equivalents of the rights granted by these patent applications. Therefore, the scope of patent application is not limited by the disclosure.

Claims (65)

An online free setting method for setting an operating parameter of a lighting device, comprising: a user interface application comprising at least one free setting algorithm, the at least one free setting algorithm being preloaded in a mobile device to Determining, by a user, conversion to at least one operational variable of an operational parameter of the illumination device, wherein the user interface application is operable and on a touch screen panel of the mobile device; The interface application is triggered or terminated by at least one setting control, and the user interface application controls to transmit at least one wireless command signal to the light emitting device via the mobile device, the at least one wireless command signal carrying the operation variable a message, wherein the operational variable is the operational parameter for processing the illumination device; and a microprocessor of the illumination device is designed to have at least one program for processing the operational variable and performing the illumination device The operating parameter; wherein the value of the operating parameter is stored in a memory of the microprocessor Repetitive performance in performance, wherein a new operational variable will replace the value of the operational parameter, the new operational variable being generated by a user selection process; wherein the operational parameter is used to control at least one of a plurality of illumination characteristics of the illumination device The plurality of illuminating characteristics are implemented by a light sensor or a moving sensor, and include a timer setting, an illuminating intensity setting, a color temperature setting, or a sensing sensitivity setting. The online free setting method according to claim 1, wherein the freely set algorithm is a simulation range scale, and the simulation range scale is realized by a visual configuration of a freely set operation factor, and the visual configuration of the freely set operation factor has a range scale simulation And an indication of a range operation rate to prompt the user to decide to set the operation parameter to an expected value, and when the freely set operation factor triggered by the user is used to interact with the range scale simulator, the user The interface application responds to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, the instantaneous state of interaction being the interaction between the freely set operation factor and the range scale simulator, the range scale simulator having the The indication symbol of the range operation rate, and synchronously displaying a momentary value of the range operation rate, wherein the range operation rate is displayed on the indicator symbol, and the indicator display value is a corresponding operation percentage or one of the operation parameter The actual operation value, when a free setting movement of the free setting operation factor is stopped, the user interface application corresponds to the selected range operation rate to generate the operation variable, and accordingly transmits a wireless command signal to the The illuminating device, the wireless command signal carries a message of the operational variable. The online free setting method of claim 2, wherein the range scale simulator is a virtual track, wherein the free set algorithm is implemented by a visual configuration of the free set operation factor, the free set operation factor coupling the virtual a track and a pointer of the range operating rate, wherein the virtual track is designed on the touch screen panel of the mobile device, wherein the free setting operation factor is slid by a user's finger and along an operating rate having the range The virtual track of the indicator slides, and when the sliding of the free setting operation factor is performed, and simultaneously displays a momentary value of the range operation rate of the range, wherein the moment value displays the indicator symbol of the range operation rate, The instantaneous value is an operation percentage or an actual operation value of the operation parameter, wherein the full length of the virtual track represents a simulated value of the maximum operating range of the operation parameter, wherein the range operation rate is when the sliding is stopped. The free set operating factor is determined by a rest position of the virtual track. The online free setting method according to claim 2, wherein the range scale simulator is a range free running subroutine, and the free setting operation factor is a virtual button, wherein the free setting algorithm is a virtual button a visual configuration implementation, the range free running subroutine integrates the virtual button and the indication symbol of the range operation rate, wherein the virtual button is designed on the mobile device Touching the screen panel, when the virtual button is continuously touched by the user's finger, the user interface application operates to trigger the range free running subroutine to gradually increase the range operation rate from a minimum value to a a maximum value, then from the maximum value to the minimum value, to complete a full cycle of a free running movement, wherein during the free running cycle, the varying instantaneous value of the range operating rate simultaneously displays the indication of the range operating rate a symbol, wherein the instantaneous value of the range operation rate is an operation percentage of the operation parameter or an actual operation value, wherein the range free running movement is immediately stopped when the user finger moves away from the virtual button, and the The range operation rate is locked at the last moment of the free running movement, wherein the length of the half of the free running movement represents an analog value of the maximum operating range of the operating parameter, wherein the range operating rate is determined, According to the length of time that the user's finger stays on the touch screen panel having the virtual button, The run length of time in a half period of the free movement. The online free setting method of claim 2, wherein the operation variable is the range operation rate, wirelessly transmitted to the illumination device, and used to convert to the operation parameter. The online free setting method of claim 2, wherein the operation variable is the operation parameter, wherein the user interface application comprises at least one subroutine to process at least one range operation rate selected by the user to be converted into An operational parameter, wherein the operational parameter is wirelessly transmitted to the illumination device. The online free setting method of claim 1, wherein the mobile device is a smart phone, a tablet computer, a PDA, a notebook computer or a remote controller to download an application from a network or a cloud server. . An LED protection lamp comprises: a lighting unit; a load and power control unit; a light sensor; a mobile sensor; a power supply unit; and an external control unit electrically connected to the load and power control unit; wherein the light unit comprises an LED light; wherein the load and power control unit comprises a microprocessor The photo sensor and the mobile sensor are electrically connected to the microprocessor, wherein the microprocessor is electrically connected to a controllable semiconductor switch, wherein the controllable semiconductor switch is electrically connected to a power source. And the LED lamp of the light emitting unit, wherein the microprocessor outputs a control signal to control the conduction rate of the controllable semiconductor switch, the conduction rate means transmitting different average electric power to drive the LED lamp to execute a plurality of illumination modes, the illumination modes being generated according to a sensing signal from the photo sensor or the motion sensor, wherein an ambient brightness sensed by the photo sensor is lower than a first preset value The mobile sensor is turned on, and the load and power control unit simultaneously manages the light emitting unit to perform a first-order brightness mode; when the light sensor senses the environment is bright When the second preset value is higher than the second preset value, the light emitting unit and the mobile sensor are both turned off by the load and power control unit; when the mobile sensor senses a mobile intrusion, the load and power control unit Management to increase the average electric power, the average electric power is transmitted to the lighting unit to perform a second-order brightness mode for a preset duration, after which the lighting unit resumes executing the first-order brightness mode, wherein the first The step brightness mode and the second order brightness mode respectively have different illumination intensities, wherein the illumination intensity of the second order brightness mode is higher than the illumination intensity of the first order brightness mode; wherein the external control unit is a wireless reception The wireless receiver is electrically connected to the microprocessor to receive and decode the at least one wireless signal into an operational variable, and the microprocessor can read and interpret the operational variable, wherein the microprocessor further includes at least one a program for processing the operational variable and adjusting a corresponding control signal, the corresponding control signal being based on the wireless receiver Receiving the operational variable to perform at least one operational parameter, wherein the operational variable represents a setting decision of a range operating rate for each functional category of the operational parameter of the LED security light, and The user is configured by an application preloaded on a mobile device, wherein the operational parameter is used to control at least one illuminating characteristic of the illuminating device. The LED protection lamp of claim 8, wherein the LED protection lamp further comprises: a user interface application comprising at least one free setting algorithm, the at least one free setting algorithm preloading the mobile device, Determining to be an operational variable by converting a user's settings, wherein the user interface application is operable and on a touch screen panel of the mobile device; when the user interface application is determined by at least one setting Triggering or ending, the user interface application controls to transmit at least one wireless command signal to the LED security light via the mobile device, the at least one wireless command signal carrying a message of the operational variable, wherein the operation The variable is the operating parameter used to process or set the LED security light. The LED protection lamp of claim 9, wherein the freely set algorithm is a simulation range scale, and the simulation range scale is implemented by a visual configuration of a freely set operation factor, the visual configuration of the freely set operation factor having a range scale And an indicator of the range operation rate of the simulator to prompt the user to determine to set the operation parameter to an expected value. When the freely set operation factor triggered by the user is used to interact with the range scale simulator, the use The interface application response is to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, and the instantaneous state of interaction is the interaction between the freely set operation factor and the range scale simulator, the range scale simulator The indicator symbol having the range operation rate, and synchronously displaying a momentary value of the range operation rate, wherein the range operation rate is displayed on the indicator symbol, and the indicator display value is a corresponding operation percentage of the operation parameter Or an actual operation a value, when a free setting movement of the free setting operation factor is stopped at at least one setting decision, the user interface application corresponds to the selected range operation rate to generate the operation variable, and accordingly transmits a wireless The command signal is given to the LED protection light, and the wireless command signal carries a message of the operation variable. The LED security light of claim 10, wherein the range scale simulator is a virtual track, wherein the free set algorithm is implemented by a visual configuration of the free set operation factor, the virtual track being coupled to the free set operation a factor and a sign of the range operation rate, wherein the free set operation factor is slid by the user's finger and slides along the virtual track of the indicator having the range operation rate, and when the freely set operation factor is slid While performing, and simultaneously displaying a changed instantaneous value of the range operation rate, wherein the instantaneous value displays the indication symbol of the range operation rate, the instantaneous value is an operation percentage or an actual operation value of the operation parameter, wherein The full length of the virtual track represents a simulated value of the maximum operating range of the operating parameter, wherein the range operating rate is determined by a free set operating factor that stops at a rest position of the virtual track when the slide is stopped. The LED security light of claim 10, wherein the range scale simulator is a range free running subroutine, and the freely set operation factor is a virtual button, wherein the freely set algorithm is a virtual button The visual configuration is implemented, the range free running subprogram integrates the virtual button and the indication symbol of the range operation rate, wherein the virtual button is designed on the touch screen panel of the mobile device, when the virtual button is used by the user When the finger touches continuously, the user interface application operates to trigger the range free running subroutine to gradually increase the range operation rate from a minimum value to a maximum value, and then from the maximum value to the minimum value to complete a complete cycle of free running movement, wherein during the free running cycle, the instantaneous value of the range operating rate of the range is simultaneously displayed at the indicator of the range operating rate, wherein the range operating rate The instantaneous value is an operation percentage of the operation parameter or an actual operation value, wherein the free running movement is immediately stopped at the moment the user finger moves away from the virtual key, and the range operation rate is locked in the free running a momentary state of the last moment of movement, wherein the length of time of the half cycle of the free running movement represents an analog value of the maximum operating range of the operating parameter, wherein the range operating rate is determined based on the user's finger staying with The length of time that the virtual button touches the screen panel is compared to the length of time of one half of the free running movement. The LED protection lamp of claim 8, wherein the wireless receiver is a Wi-Fi wireless receiver, a Bluetooth wireless receiver, a ZigBee wireless receiver or a radio frequency wireless receiver. The LED protection lamp of claim 8, wherein the operation parameter is used to set a timer for performing a manual operation illumination mode, wherein the protection light is controlled by the photo sensor and the timer. And the timer is used to perform a general illumination mode of the mobile sensor with temporary deactivation. The LED protection lamp of claim 14, wherein the timer is a time length setting timer or a clock time setting timer. The LED protection lamp of claim 8, wherein the operation parameter is a movement delay time for setting the movement sensor, and when the movement sensor detects a movement intrusion, a highlight illumination is immediately Triggered by the load and power control unit and continuously illuminate the movement delay time. The LED protection lamp of claim 8, wherein the operation parameter is used to set the sensing distance of the motion sensor. The LED protection lamp of claim 8, wherein the operation parameter is used to set the illumination intensity of the first-order brightness mode or the second-order brightness mode. The LED protection lamp of claim 8, wherein the operation parameter is used to set the color temperature of the first-order brightness mode or the second-order brightness mode. A security light control device comprising: a load and power control unit; a light sensor; a mobile sensor; a power supply unit; and an external control unit; wherein the protection light control device is electrically connected to a light-emitting load, wherein the load and power control The unit includes a controller electrically connected to the photo sensor and the mobile sensor, wherein the controller is electrically connected to a controllable semiconductor switch, wherein the controllable semiconductor switch is electrically Connecting the illuminating load and a power source, wherein the controller outputs a control signal to control the conduction rate of the steerable semiconductor switch, the conduction rate is to transmit different average electric power to drive the illuminating load to generate a plurality of illumination modes The illumination modes are generated according to the sensing signals from the photo sensor or the motion sensor. When the ambient brightness sensed by the photo sensor is lower than a first preset value, the The mobile sensor is turned on, and the load and power control unit simultaneously manages the lighting load to perform a first-order brightness mode, when the environment sensed by the light sensor is bright When the mobile sensor is sensed by a load and power control unit, the load and power control unit Management to increase the average electric power, the average electric power is transmitted to the illuminating load to generate a second-order brightness mode for a predetermined duration, after which the illuminating load returns to the first-order brightness mode, wherein the first The step brightness mode and the second order brightness mode respectively have different illumination intensities, wherein the illumination intensity of the second order brightness mode is higher than the illumination intensity of the first order brightness mode; wherein the external control unit is a wireless receiver The wireless receiver is electrically connected to the controller to receive and decode the wireless command to become at least one operational variable of the operating parameter, the operating parameter is used to operate the security light control device, wherein the controller further includes at least one subroutine The subroutine is used to process the wireless receiver The operational variable received, wherein the operational variable is set by a user through an application, the application being installed in a mobile device, wherein the operational parameter is used to control at least one illumination characteristic of the security light control device. The security light control device of claim 20, wherein the wireless receiver is a Wi-Fi wireless receiver, a Bluetooth wireless receiver, a ZigBee wireless receiver, or a radio frequency wireless receiver. The security light control device of claim 20, wherein the operation parameter is used to set a timer for performing a manual operation illumination mode, wherein the protection light is controlled by the light sensor and the timer And the timer is used to perform a general illumination mode of the mobile sensor with temporary deactivation. The security light control device of claim 22, wherein the timer is a time length setting timer or a clock time setting timer. The security light control device of claim 20, wherein the operation parameter is used to set a movement delay time of the mobile sensor, and when the mobile sensor detects a mobile intrusion, a highlight illumination is immediately The load and power control unit triggers and continuously illuminates the movement delay time. The security light control device of claim 20, wherein the operational parameter is used to set the sensing distance of the motion sensor. The security light control device of claim 20, wherein the operational parameter is used to set the illumination intensity of the first-order luminance mode or the second-order luminance mode. The security light control device of claim 20, wherein the operation parameter is used to set a color temperature of the first-order brightness mode or the second-order brightness mode. The security light control device of claim 20, further comprising: a user interface application comprising at least one free setting algorithm preloaded in the mobile device to determine a user setting Converting to the operational variable, wherein the user interface application is operable and on a touch screen panel of the mobile device; when the user interface application is triggered or knotted by at least one setting The user interface application controls to transmit at least one wireless command signal to the LED security light control device via the mobile device, the at least one wireless command signal carrying a message of the operational variable, wherein the operational variable It is used to process or set the operating parameters of the LED security light control device. The security light control device of claim 20, wherein the freely set algorithm is a simulated range scale, and the analog range scale is implemented by a visual configuration of a freely set operating factor, the visual configuration of the freely set operating factor having a range a scale simulator and an indication of a range operation rate to prompt the user to determine the operation parameter to an expected value, when the freely set operation factor triggered by the user is used to interact with the range scale simulator, The user interface application responds to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, and the instantaneous state of the interaction is the interaction between the freely set operation factor and the range scale simulator, the range scale simulation The indicator has the indication range of the range operation rate, and synchronously displays a momentary value of the range operation rate, wherein the range operation rate is displayed on the indicator symbol, and the indicator display value is an operation of the corresponding operation parameter Percentage or an actual operational value, when the freely set operating factor is set freely When the motion is stopped, the user interface application corresponds to the selected range operation rate to generate the operation variable, and accordingly transmits a wireless command signal to the LED protection light, the wireless command signal carries the operation variable a message. The security light control device of claim 29, wherein the range scale simulator is a virtual track, wherein the free set algorithm is implemented by a visual configuration of the free set operation factor, the virtual track being coupled to the free setting An operating factor and the indicator of the range operating rate, wherein the freely set operating factor is slid by the user's finger and slid along the virtual track of the indicator having the range operating rate, and when the freely set operating factor When the sliding is performed, a momentary value of the range operation rate of the range is displayed, wherein the moment value displays the indicator of the range operation rate, and the moment value is the operation An operation percentage of the parameter or an actual operation value, wherein the full length of the virtual track represents a simulated value of the maximum operating range of the operating parameter, wherein the range operating rate is stopped by the free setting operation factor when the sliding stops Determined at a rest position of the virtual track. The security light control device of claim 29, wherein the range scale simulator is a range free running subroutine, and the free set operation factor is a virtual button, wherein the free set algorithm is performed by the virtual button a visual configuration implementation, the range free running subprogram integrates the virtual button and the indicator of the range operation rate, wherein the virtual button is designed on the touch screen panel of the mobile device, when the virtual button is used When the finger touches continuously, the user interface application operates to trigger the range free running subroutine to gradually increase the range operation rate from a minimum value to a maximum value, and then from the maximum value to the minimum value, Completing a complete cycle of a free running movement, wherein during the free running period, the instantaneous value of the range operating rate of the range simultaneously displays the indicator of the range operating rate, wherein the instantaneous value of the range operating rate is the operating parameter An operational percentage or an actual operational value, wherein the user's finger moves away from the virtual key, the Immediately stopped by the running movement, and the range operating rate is locked at the last moment of the free running movement, wherein the length of the half of the free running movement represents an analog value of the maximum operating range of the operating parameter The range operation rate is determined according to the length of time that the user's finger stays on the touch screen panel having the virtual button, compared to the length of time of the half cycle of the free running movement. The security light control device of claim 20, wherein the controller is a programmable microprocessor for generating the control signal. The security light control device of claim 20, wherein the controller is a special application integrated circuit for generating the control signal. The security light control device according to claim 20, wherein the security light control device In order to be detachably connected to an LED lighting load, through a screwing or inserting configuration, wherein the security light control device is provided with a socket base, and the LED lighting load is provided with a screw-in connector or a pair The needle twists the joints to electrically connect to each other. A protection lamp control device comprises: a load and power control unit; a light sensor; a mobile sensor; a power supply unit; and an external control unit; wherein the protection lamp control device is electrically connected The illuminating load, wherein the load and power control unit comprises a controller, wherein the controller is electrically connected to the controllable semiconductor switch, wherein the steerable semiconductor switch is electrically connected between the illuminating load and a power source, wherein The controller outputs a control signal to control a conduction rate of the controllable semiconductor switch, the conduction rate refers to transmitting different electrical power to drive the illumination load to generate different illumination modes, and the illumination modes are based on the light perception The sensor or the sensing signal of the motion sensor is generated; when the ambient brightness sensed by the light sensor is lower than a first preset value, the motion sensor is used by the load and power control unit Turning on, and the illuminating load is maintained in a closed state to perform a first-order brightness mode, when the ambient brightness sensed by the photo sensor is higher than a second preset value The load and power control unit switches the mobile sensor to turn off. When the mobile sensor senses a mobile intrusion, the load and power control unit instantly turns on the light-emitting load to perform a high-order brightness mode for a short period of time. a preset duration, after which the illuminating load is restored to a closed state; wherein the external control unit is a wireless receiver, the wireless receiver is electrically connected to the controller to receive and decode the wireless command to become at least one operating parameter Operation variable for operating the protection light control device, wherein the control The controller further includes at least one subroutine for calculating and setting the operation variable received from the wireless receiver, wherein the operation variable indicates a setting decision made by the user through an application The application is installed in a mobile device, wherein the operational parameter is used to control at least one illuminating characteristic of the illuminating device. The security light control device of claim 35, wherein the wireless receiver is a Wi-Fi wireless receiver, a Bluetooth wireless receiver, a ZigBee wireless receiver, or a wireless receiver. The security light control device of claim 35, wherein the operation parameter is used to set a timer for performing a manual operation illumination mode, wherein the security light is controlled by the light sensor and the timer And the timer is used to perform a general illumination mode of the mobile sensor with temporary deactivation. The security light control device of claim 37, wherein the timer is a time length setting timer or a clock time setting timer. The security light control device of claim 35, wherein the operation parameter is used to set a movement delay time of the motion sensor, and when the mobile sensor detects a mobile intrusion, a highlight illumination is immediately Triggered by the load and power control unit and continuously illuminate the movement delay time. The security light control device of claim 35, wherein the operational parameter is used to set the sensing distance of the motion sensor. The security light control device of claim 35, wherein the operational parameter is used to set the illumination intensity of the high-order luminance mode. The security light control device of claim 35, wherein the operational parameter is used to set the color temperature of the high-order brightness mode. The security light control device of claim 35, further comprising: a user interface application comprising at least one free setting algorithm, the at least one free setting algorithm preloading the mobile device to convert a user's The setting decision becomes the operation variable, wherein the user interface application is operable And on a touch screen panel of the mobile device; when the user interface application is triggered or terminated by at least one setting decision, the user interface application controls to transmit at least one via the mobile device The wireless command signal is sent to the LED protection light control device, and the at least one wireless command signal carries a message of the operation variable, wherein the operation variable is the operation parameter for processing or setting the LED protection light control device. The security light control device of claim 43, wherein the freely set algorithm is a simulated range scale, and the simulated range scale is implemented by a visual configuration of a freely set operating factor, the visual configuration of the freely set operating factor having a range a scale simulator and an indication of a range operation rate to prompt the user to determine the operation parameter to an expected value, when the freely set operation factor triggered by the user is used to interact with the range scale simulator, The user interface application responds to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, and the instantaneous state of the interaction is the interaction between the freely set operation factor and the range scale simulator, the range scale simulation The indicator has the indication range of the range operation rate, and synchronously displays a momentary value of the range operation rate, wherein the range operation rate is displayed on the indicator symbol, and the indicator display value is an operation of the corresponding operation parameter Percentage or an actual operational value, when the freely set operating factor is set freely When the action is stopped, the user interface application corresponds to the selected range operation rate to generate the operation variable, and accordingly transmits a wireless command signal to the LED protection light, the wireless command signal carries A message of the operation variable. The security light control device of claim 44, wherein the range scale simulator is a virtual track, wherein the free set algorithm is implemented by a visual configuration of the free set operation factor, the virtual track being coupled to the free setting An operating factor and the indicator of the range operating rate, wherein the freely set operating factor is slid by the user's finger and slid along the virtual track of the indicator having the range operating rate, and when the freely set operating factor Sliding At the same time, a momentary value of the range operation rate of the range is displayed, wherein the moment value displays the indicator of the range operation rate, and the moment value is an operation percentage or an actual operation value of the operation parameter, wherein the The full length of the virtual track represents a simulated value of the maximum operating range of the operating parameter, wherein the range operating rate is determined by a free set operating factor that stops at a rest position of the virtual track when the slide is stopped. The security light control device of claim 44, wherein the range scale simulator is a range free running subroutine, and the freely set operation factor is a virtual button, wherein the freely set algorithm is performed by the virtual button a visual configuration implementation, the range free running subprogram integrates the virtual button and the indicator of the range operation rate, wherein the virtual button is designed on the touch screen panel of the mobile device, when the virtual button is used When the finger touches continuously, the user interface application operates to trigger the range free running subroutine to gradually increase the range operation rate from a minimum value to a maximum value, and then from the maximum value to the minimum value, Completing a complete cycle of a free running movement, wherein during the free running period, the instantaneous value of the range operating rate of the range simultaneously displays the indicator of the range operating rate, wherein the instantaneous value of the range operating rate is the operating parameter An operational percentage or an actual operational value, wherein the user's finger moves away from the virtual key, the Immediately stopped by the running movement, and the range operating rate is locked at the last moment of the free running movement, wherein the length of the half of the free running movement represents an analog value of the maximum operating range of the operating parameter The range operation rate is determined according to the length of time that the user's finger stays on the touch screen panel having the virtual button, compared to the length of time of the half cycle of the free running movement. The security light control device of claim 35, wherein the controller is a programmable microprocessor for generating the control signal. The security light control device of claim 35, wherein the controller is a special The integrated circuit is applied to generate the control signal. The security light control device of claim 35, wherein the security light control device is detachably connected to an LED light-emitting load via a screw-in or an inserted configuration, wherein the security light control device A socket base is disposed, and the LED light-emitting load is provided with a screw-in joint or a double-needle twist joint for electrically connecting to each other. The security light control device of claim 35, wherein the security light control device is non-detachably connected to an LED lighting load. An LED protection lamp control device comprises: a load and power control unit; a light sensor; a power supply unit; and an external control unit electrically connected to the load and the power control unit; wherein the LED protection lamp The control device is electrically connected to a light-emitting load, wherein the load and power control unit comprises a controller, wherein the controller is electrically connected to a controllable semiconductor switch, wherein the controllable semiconductor switch is electrically connected to a power source and the Between the illuminating loads, wherein the controller outputs a control signal to control a conduction rate of the steerable semiconductor switch, the conduction rate is to transmit different average electric power to drive the illuminating load to generate different illumination modes, the illumination The mode is generated according to the sensing signal from the photo sensor; when the ambient brightness sensed by the photo sensor is lower than a first preset value, the lighting load is turned on by the load and power control unit To generate a first-order brightness mode for a first predetermined duration, after which the illumination load is switched to a second-order brightness mode when the light When the brightness of the environment sensed by the detector is higher than a second preset value, the light-emitting load is turned off by the load and power control unit; wherein the external control unit is a wireless receiver, and the wireless receiver is electrically connected to the The controller, to receive and decode the wireless command, becomes an operational variable, wherein The controller further includes at least one subroutine for processing the operation variable, wherein the operation variable indicates a setting decision made by the user, the operation variable is set by the user through an application, and the application is installed in the a mobile device, wherein the operational parameter is for controlling at least one illuminating characteristic of the illuminating device. The LED security light control device of claim 51, wherein the wireless receiver is a Wi-Fi wireless receiver, a Bluetooth wireless receiver, a ZigBee wireless receiver or a radio frequency wireless receiver. The LED security light control device of claim 51, wherein the operation parameter is used to control the length of the first preset duration for performing the first-order luminance mode. The LED protection lamp control device of claim 51, wherein the operation parameter is used to set the illumination intensity of at least one of the first-order brightness mode or the second-order brightness mode. The LED security light control device of claim 51, further comprising: a user interface application comprising at least one free setting algorithm, the at least one free setting algorithm preloading the mobile device to convert a user The setting determines to be an operational variable, wherein the user interface application is operable and on a touch screen panel of the mobile device; when the user interface application is triggered or terminated by at least one setting decision, The user interface application controls to transmit at least one wireless command signal to the LED security light control device via the mobile device, wherein the at least one wireless command signal carries a message of the operational variable, wherein the operational variable is used To process or set the operating parameters of the LED security light control device. The LED security light control device according to claim 55, wherein the free setting algorithm is a simulation range scale, and the simulation range scale is realized by a visual configuration of a freely set operation factor, and the visual configuration of the free setting operation factor has a a range scale simulator and an indication of a range of operating rates to cause the user to decide to set the operational parameter to a desired value when triggered by the user When the free setting operation factor is used to interact with the range scale simulator, the user interface application responds to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, and the interactive transient state is the free setting operation. a factor and an interaction between the range scale simulators, the range scale simulator having the indicator of the range operation rate, and simultaneously displaying a momentary value of the range operation rate, wherein the range operation rate is displayed at the indicator The value displayed by the indicator symbol is a corresponding operation percentage of the operation parameter or an actual operation value. When a free setting movement of the free setting operation factor is stopped, the user interface application corresponds to the selected one. The range operation rate is to generate the operation variable, and accordingly, a wireless command signal is transmitted to the LED protection light, and the wireless command signal carries a message of the operation variable. The LED security light control device of claim 56, wherein the range scale simulator is a virtual track, wherein the free set algorithm is implemented by a visual configuration of the free set operation factor, the virtual track coupling the freedom Setting an operating factor and the indicator of the range operating rate, wherein the virtual track is designed on the touch screen panel of the mobile device, wherein the free setting operation factor is slid by a user's finger and operates along the range The virtual track of the indicator slides, and when the sliding of the free setting operation factor is performed, and simultaneously displays a momentary value of the range operation rate of the variation, wherein the instantaneous value displays the indication of the operating rate in the range a symbol, the instantaneous value being an operational percentage of the operational parameter or an actual operational value, wherein the full length of the virtual track represents a simulated value of the maximum operating range of the operational parameter, wherein the range operating rate is stopped by sliding At this time, the free setting operation factor is determined by stopping at a rest position of the virtual track. The LED security light control device of claim 56, wherein the range scale simulator is a range free running subroutine, and the free set operation factor is a virtual button, wherein the free set algorithm is the virtual button a visual configuration implementation, the range free running subroutine integrated with the virtual button and the van The indicator of the operation rate, wherein the virtual button is designed on the touch screen panel of the mobile device, and when the virtual button is continuously touched by the user's finger, the user interface application operates to trigger the range Freely running the subroutine to gradually increase the range operating rate from a minimum to a maximum, then from the maximum to the minimum, to complete a full cycle of free running movements, during which the free running period The instantaneous value of the range operation rate simultaneously displays the indicator symbol of the range operation rate, wherein the instantaneous value of the range operation rate is an operation percentage of the operation parameter or an actual operation value, wherein the user finger is from the At the moment when the virtual button is removed, the free running movement is immediately stopped, and the range operation rate is locked at the last moment of the free running movement, wherein the length of the half of the free running movement represents the operating parameter. The simulated value of the maximum operating range, wherein the range operating rate is determined based on the user's finger The length of time to stay in the touch screen panel having a virtual key is compared to the free-running half the length of the period of time of movement. The LED security light control device of claim 51, wherein the controller is a programmable microprocessor for generating the control signal. The LED security light control device of claim 51, wherein the controller is a special application integrated circuit (ASIC) for generating the control signal. The LED security light control device according to claim 51, wherein the security light control device is detachably connected to an LED lighting load, and is configured by a screwing or an insertion, wherein the security light control The device is provided with a socket base, and the LED light-emitting load is provided with a screw-in joint or a double-needle twist joint for electrically connecting to each other. An online free setting method for setting operating parameters of a ceiling fan having a light socket set, comprising: a user interface application comprising at least one free setting algorithm, the at least one free setting algorithm being preloaded with a mobile device, To convert a user's Setting at least one operational variable that determines an operational parameter of the ceiling fan of the light fixture set, wherein the user interface application is operable and on a touch screen panel of the mobile device; when the user interface The application is triggered or terminated by at least one setting control, and the user interface application controls to transmit at least one wireless command signal to the ceiling fan having the light socket set via the mobile device, the at least one wireless command signal carrying the a message of the operational variable, wherein the operational variable is the operational parameter for processing or setting the ceiling fan having the light sleeve set; a microprocessor of the illumination device is designed to have at least one program for processing the operational variable And performing the operating parameter of the ceiling fan having the light sleeve set; wherein the value of the operating parameter is stored in a memory of the microprocessor for performance repeat performance, wherein a new operational variable will replace the a numerical value of an operational parameter generated by a user selection process; wherein the operational parameter is used to control a set having a light sleeve A plurality of luminescent and electrical characteristics of at least one of a ceiling fan, comprising a plurality of light emitting characteristics and electrical timer setting, speed setting of the fan, the fan rotation direction setting, and the light emission intensity setting color temperature setting. The online free setting method of claim 62, wherein the freely set algorithm is a simulated range scale, and the simulated range scale is implemented by a visual configuration of a freely set operation factor, the visual configuration of the freely set operation factor having a range scale The simulator and an indication of a range operation rate to prompt the user to determine to set the operation parameter to an expected value, and when the freely set operation factor triggered by the user is used to interact with the range scale simulator, the use The interface application response is to gradually adjust the value of the range operation rate according to the instantaneous state of the interaction, and the instantaneous state of interaction is the interaction between the freely set operation factor and the range scale simulator, the range scale simulator The indicator having the range operation rate, and simultaneously displaying the range operation rate a momentary value, wherein the range operation rate is displayed in the indicator symbol, the indicator value displayed is a corresponding operation percentage of the operation parameter or an actual operation value, and a free setting movement of the free setting operation factor When stopped, the user interface application corresponds to the selected range operation rate to generate the operation variable, and accordingly transmits a wireless command signal to the ceiling fan of the light set, the wireless command signal carries the operation A message of a variable. The online free setting method as claimed in claim 62, wherein the mobile device is a smart phone, a tablet computer, a PDA, a notebook computer or a remote controller with a selected range, from the network or the cloud server. Download an app. The online free setting method of claim 62, wherein the ceiling fan is a DC motor fan, and the lamp set is an LED lighting device.