CN107690837B - Direct-modulation light-modulation device, corresponding direct-modulation light-modulation lighting system and direct-modulation light-modulation method - Google Patents

Abstract

A direct-modulated light modulating device comprising: at least one control unit, wherein the control unit comprises at least one signal transmitting unit, wherein the signal transmitting unit can generate at least one control signal, wherein the control signal corresponds to the optical parameter of the lighting device; and at least one direct-modulation signal processing unit, wherein the direct-modulation signal processing unit is controlled by the control unit, wherein the direct-modulation signal unit comprises at least one signal receiving and sending unit and a signal processing unit, wherein the signal processing unit comprises a storage module, the storage module stores the optical parameters of at least one lighting device, the signal receiving and sending unit receives the control signal to generate an intermediate signal and transmits the intermediate signal to the signal processing unit, the signal processing unit calls the corresponding optical parameters in the storage module to obtain at least one adjusting signal, and the adjusting signal adjusts the lighting device.

Description

Direct-modulation light-modulation device, corresponding direct-modulation light-modulation lighting system and direct-modulation light-modulation method

Technical Field

The invention relates to the field of lighting control, in particular to a direct-modulation dimming device and a corresponding direct-modulation dimming lighting system.

Background

The electric lamp is the most great invention of the 20 th century for human beings, changes the life style of people invisibly and is not exaggeratedly bright for all human beings due to the appearance of the electric lamp. With the development of the times, the shape and structure of electric lamps have been changed with the ground, and unlike the initial tungsten filament electric lamps, various types of lamps such as induction lamps, LED lamps, flexible lamp panels, etc. have appeared on the market, but in any type of lamp, these lamps include a control switch and a corresponding light emitting element, and these control switches are adapted to control the on and off of the light emitting element.

Light fixtures are suitable for use in various scenes in daily life, such as home applications, office applications, stage applications, and the like. As can be seen from the above, the conventional light fixture includes the control switch and the light-emitting element, wherein one can control the control switch to turn on and off the light-emitting element. Specifically, when one needs to turn on the light emitting element, the control switch is controlled to turn on an operating circuit of the light emitting element; when one needs to turn off the light emitting element, the control switch emits a closing signal, and the closing signal may close the operating circuit of the light emitting element in such a way as to close the control switch. However, such conventional lamps are far from meeting the living needs of people, that is, people are not satisfied with lamps which can only achieve one light emitting effect.

In life, people need to be able to regulate and control the luminosity and the lighting effect of the lamp, and in this way, the lamp is suitable for different needs of people. For example, when a person gets up and turns on the light late at night, because the human eye is sensitive to the brightness of the light in a dark environment, it is more desirable to choose a light fixture that can emit a more moderate light, i.e., the light level when getting up and turning on the light is only 50% or even 10% of the normal light level. Or for example, in a dance lighting arrangement, people often need that the lighting effect emitted by the lamp can be changed along with the change of stage effect. For example, in the living environment, people often need to set the lighting effects with different luminosity according to the requirements of different natural environments. In summary, the conventional open-close type lamps are far from satisfying people's needs, and people need a lighting device capable of freely adjusting the effect of the luminous line to satisfy different needs in life.

In order to meet the needs of people, various dimming methods related to lighting devices are available on the market, and common lamp dimming modes include sectional dimming, stepless dimming, intelligent scene dimming and the like. The sectional dimming method is to control the control switch to continuously and rapidly turn off the working circuit of the light-emitting element, so that the luminous luminosity of the light-emitting element can be sequentially and sectionally changed from high to low or from low to high under the control of the logic controller, and further the luminous luminosity of the light-emitting element is adjusted. However, the segmented dimming method has a drawback in that the light emitting element continuously flickers during the dimming process, which causes uncomfortable stimulus to human eyes. In addition, when a user uses the lamp using the sectional dimming method, once the user has dimmed, the user needs to operate the dimming process again from the beginning. Namely, the segmented dimming method has the defects of time consumption and poor dimming effect. In addition, the lamp adopting the stepless dimming mode is low in response speed and inconvenient to use. For example, an external intelligent device is often required for a lamp using intelligent scene dimming, so that economic burden of a user is increased, and once the intelligent device fails, the user cannot regulate and control the lamp. And the remote controller is used for controlling the dimming mode of the lamp, the mode of regulating and controlling the lamp by using the remote controller has higher requirement on the lamp, and the application range of the lamp is too narrow. In summary, the existing lamp control method and the lamp control device have the problems.

It is also worth mentioning that since the control switch of a conventional luminaire is usually arranged as an active switch, and the active switch is arranged at a specific place. When a user needs to control the light fixture, the user must go to a specific place to control the light fixture, which is an unnecessary burden for the user. In addition, due to the characteristic of active light-on, the control switch of the existing traditional lamp cannot be arranged at a plurality of places at the same time to control the traditional lamp, and the switch characteristic of the existing traditional lamp makes double-control and multi-control dimming difficult to implement.

Furthermore, from the viewpoint of environmental protection and long-term utilization, the LED lamp is exemplified. The life of existing LED lamps has generally exceeded 35000 hours, that is, if a lamp is operated for 6 hours a day, from 18 o 'clock to 24 o' clock; then the life of a lamp can be as long as 35000 ÷ 6 ÷ 365 ≈ 16 years, but if a traditional remote control with a battery is used to control the lamp, the remote control is difficult to have such a long life; if the traditional dimmer switch is adopted, the wires are troublesome to bury and inconvenient to operate. Therefore, it is necessary to develop a light modulation device which has a long service life, at least matches with the service life of the lamp, is intuitive and simple to operate, is fast and convenient to install, saves energy and is environment-friendly.

Disclosure of Invention

The present invention provides a direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming lighting system comprises at least one direct-dimming device and at least one lighting device, and the direct-dimming device can send a dimming signal to remotely control the lighting device.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming device can work in different dimming control modes and different dimming control programs.

The present invention is directed to a directly dimming device, a directly dimming lighting system and a directly dimming method thereof, so that the directly dimming lighting system can be adjusted in multiple ways to meet different needs of users, i.e., the directly dimming lighting system can be configured with different control programs.

The present invention provides a direct-dimming device, a direct-dimming lighting system and a direct-dimming method thereof, wherein a user can directly and quickly call the light intensity and color of the direct-dimming lighting system through the direct-dimming device to control the light emitting effect of at least one lighting device, thereby facilitating the use of the user.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming device is convenient for a user to directly select the luminosity of the lighting device so as to meet the requirements of the user on different ambient light rays in life.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein a user can preset luminosity parameters of the direct-dimming lighting system according to own preference, so that the user can quickly and conveniently directly call the preset luminosity parameters in the direct-dimming lighting system through the direct-dimming device to regulate and control the lighting effect of at least one lighting device, namely the luminosity of the direct-dimming lighting system can be selected by himself.

The present invention provides a direct-dimming lighting device, a direct-dimming lighting system and a direct-dimming method thereof, wherein the luminosity parameters of the lighting device can be gradually controlled, so that the lighting effect of the lighting device can be controlled in a gradual control manner, and the lighting device and the human eyes are protected in this manner.

The invention aims to provide a direct-dimming lighting device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming lighting system comprises a storage module, and a user can independently select the light-emitting effect of the lighting device and store specific luminosity parameters in the storage module so as to conveniently and quickly call the specific luminosity parameters at any time, namely the direct-dimming lighting system has a memory function.

The present invention provides a direct-dimming lighting device, a direct-dimming lighting system and a direct-dimming method thereof, wherein a control unit and a direct-dimming signal processing unit of the direct-dimming lighting device realize signal transmission via wireless signals, so as to facilitate installation of the direct-dimming lighting device, i.e., the installation position of the direct-dimming lighting device is not limited.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein a special coding mode is adopted between a control unit and a direct-dimming signal processing unit for direct-dimming signal transmission, so that the signal transmission in the direct-dimming lighting system is ensured to have high reliability, and the control unit and the direct-dimming signal processing unit can perform signal transmission in an accurate and efficient mode.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the control unit comprises an energy supply module, so that the control unit is implemented as a passive switch, and the setting position of the direct-dimming lighting system can be unlimited.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the control unit can be implemented in a self-energy-production mode, so that the direct-dimming device has the advantages of no wiring, no maintenance and no battery power supply.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the control unit can control a plurality of lighting devices simultaneously, and the lighting devices are also controlled by the control units, so that the direct-dimming lighting system realizes double control and even multi-control.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the control unit is implemented as self-energy-production equipment, namely micro-energy acquisition technology is arranged in the control unit, and the control unit can realize self-energy production by utilizing various micro-energy, so that passive control is realized.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the control unit can realize the control of the lighting device without external energy, so that the energy is greatly saved.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming lighting system is organically combined with an electrician switch and the lighting industry.

The present invention is directed to a directly dimming device, a directly dimming lighting system and a directly dimming method thereof, wherein the directly dimming device can be used for various lighting devices in the prior art, i.e., the directly dimming device can be applied to the lighting devices in the prior art to form the directly dimming lighting system.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming lighting system has the advantages of simplicity and intuition in operation, rapidness and convenience in installation, energy conservation and environmental friendliness.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming lighting system has the effects of direct dimming, wireless control, easiness in arrangement, long service life, economy, practicability, energy conservation and environmental protection.

The invention aims to provide a direct-dimming device, a corresponding direct-dimming lighting system and a direct-dimming method, wherein the direct-dimming method can realize the effect of rapid dimming without the cooperation of APP and complex and expensive hardware, and the dimming process is visual, convenient, simple and practical.

In order to achieve the above object, the present invention provides a direct-adjusting light-adjusting device, adapted to adjust optical parameters of at least one lighting device, comprising: at least one control unit, wherein the control unit comprises at least one signal transmitting unit, wherein the signal transmitting unit can generate at least one control signal and transmit the control signal, wherein the control signal corresponds to the optical parameter of the lighting device; and at least one direct modulation signal processing unit, wherein the direct modulation signal processing unit is controlled by the control unit, wherein the direct modulation signal unit comprises at least one signal receiving and sending unit and a signal processing unit, wherein the signal processing unit comprises a storage module, the storage module stores the optical parameter of at least one lighting device, the signal receiving and sending unit receives the control signal to generate an intermediate signal and transmits the intermediate signal to the signal processing unit, the signal processing unit calls the corresponding optical parameter basis in the storage module to obtain at least one adjusting signal, and the adjusting signal adjusts the lighting device.

In some embodiments, the control unit includes at least one driving module, wherein the driving module includes at least one control key, and the control key generates the control signal in a one-to-one correspondence.

In some embodiments, the control unit includes at least one energy generation module, wherein the driving module drives the energy generation module to generate energy, and the driving module and the energy generation module form an energy supply module, wherein the energy supply module supplies energy to the direct-modulation light-modulating device.

In some embodiments, the control unit comprises at least one energy module, wherein the energy module and the driving module form an energy supply module, and the energy supply module supplies energy to the direct-modulation light-modulating device.

In some embodiments, wherein the optical parameter of the lighting device is selected from one or a combination of an optical parameter and a light color parameter of the lighting device.

In some embodiments, the signal processing unit comprises a processing module, wherein the storage module is communicatively coupled to the processing module, and the adjustment signal is obtained by the processing module receiving the intermediate signal and invoking the corresponding optical parameter in the storage module.

In some embodiments, the signal processing unit includes a controlled module, wherein the controlled module is disposed corresponding to the processing module, the processing module controls the controlled module to change between a regulation state and a non-regulation state, and when the controlled module is in the regulation state, the controlled module changes an operating circuit of the lighting device.

In some embodiments, the controlled module sends out at least one adjustment start signal and at least one adjustment stop signal under the control of the driving module, wherein the adjustment start signal adjusts the start of the change of the optical parameter of the lighting device, and the adjustment stop signal adjusts the end of the change of the optical parameter of the lighting device to obtain at least one preselected optical parameter.

In some embodiments, the controlled module is linked to the storage module, and the storage module stores the preselected optical parameters obtained by the controlled module.

In some embodiments, the signal processing unit comprises at least one determining module, wherein the determining module is communicatively connected to the processing module, and the determining module determines and controls the adjusting state and the non-adjusting state of the controlled module.

In some embodiments, the signal processing unit includes at least one safety module, wherein the safety module is linked to the signal receiving and sending unit and the signal processing unit to stabilize the working state of the direct-modulation signal processing unit.

In some embodiments, the signal sending unit comprises at least one encoding component, and the signal sending module comprises at least one decoding module, wherein the encoding component encodes the generated control signal, and the decoding module decodes the control signal into the intermediary signal.

In some embodiments, the encoding procedures between the encoding component and the decoding module are in one-to-one correspondence.

In some embodiments, the control unit and the direct-modulation signal processing unit may be in communication with each other in one or a combination of a wireless manner and a wired manner.

In some embodiments, the driving module and the power generation module are communicated with each other by one or a combination of electromagnetic power generation, high-frequency wireless power generation and mechanical piezoelectric power generation.

In some embodiments, the control unit may be implemented as one or a combination of a rocker switch, a reciprocating switch, or an inductive switch.

According to another aspect of the present invention, there is provided a direct dimming lighting system comprising: at least one lighting device, wherein the lighting device comprises at least one lighting unit, and optical parameters of the lighting unit are adjusted to different values; at least one control unit, wherein the control unit comprises at least one signal transmitting unit, wherein the signal transmitting unit can generate at least one control signal, wherein each control signal corresponds to the optical parameter of the lighting device; and at least one direct modulation signal processing unit, wherein the direct modulation signal processing unit is controlled by the control unit, wherein the direct modulation signal unit comprises at least one signal receiving and sending unit and a signal processing unit, wherein the signal processing unit comprises a storage module, the storage module stores the optical parameters of the lighting device, the signal receiving and sending unit receives the control signal to generate an intermediate signal and transmits the intermediate signal to the signal processing unit, the signal processing unit calls the corresponding optical parameters in the storage module to obtain at least one adjusting signal, and the adjusting signal adjusts the lighting device.

In some embodiments, a plurality of the control units control one of the direct-modulation signal processing units in common, or one of the control units controls a plurality of the direct-modulation signal processing units.

In some embodiments, wherein the direct-modulated signal processing unit is built-in to the lighting device.

In some embodiments, wherein the direct-tone signal processing unit is in independent communication with the lighting device.

According to another aspect of the present invention, there is provided a luminaire, conditioned by at least one control signal, comprising: at least one lighting device, wherein the lighting device comprises at least one lighting unit, and optical parameters of the lighting unit are adjusted to different values; and at least one direct-modulation signal processing unit, wherein the direct-modulation signal unit comprises at least one signal receiving and sending unit and a signal processing unit, the signal processing unit comprises a storage module, the storage module stores the optical parameter of at least one lighting device, the signal receiving and sending unit receives the control signal to generate an intermediary signal and transmits the intermediary signal to the signal processing unit, the signal processing unit calls the corresponding optical parameter in the storage module to obtain at least one regulating signal, and the regulating signal regulates the lighting device.

According to another aspect of the present invention, there is provided a method for dimming a direct-dimming lighting system adapted to dim at least one optical parameter of a lighting device, comprising the steps of:

a: receiving at least one control signal by at least one control unit, wherein the control signal corresponds to the optical parameter;

b: receiving and processing the control signal through at least one adjusting signal processing unit to obtain at least one adjusting signal, wherein the adjusting signal corresponds to the optical parameter; and

c: and adjusting the lighting device to pass through the adjusting signal.

In some embodiments, wherein the optical parameter of the lighting device is selected from one or a combination of an optical parameter and a light color parameter of the lighting device.

In some embodiments, wherein said step a further comprises the steps of:

a1: receiving at least one starting signal through a driving module;

a2: coding the starting signal into the control signal through a coding component; and

a3: and sending the control signal to the control module.

In some embodiments, wherein said step B further comprises the steps of:

b1: receiving the control signal;

b2: decoding the control signal into at least one intermediate signal through a decoding module; and

b3: processing the intermediate signal into the adjustment signal.

In some embodiments, wherein the step B3 further comprises the steps of:

b31: judging the intermediary signal through a judging module to obtain at least one judging result; and

b32: and selecting a module according to the judgment result to obtain the adjusting signal.

In some embodiments, wherein the B32 further comprises the steps of:

b321: calling a specific optical parameter in the storage module according to the intermediate signal; and

b322: and processing the specific optical parameter to obtain the adjusting signal.

In some embodiments, wherein the B32 further comprises the steps of:

B321A: calling a controlled module to send out at least one regulation starting signal, wherein the regulation starting signal

Adjusting the optical parameters of the lighting device to start changing;

B322A: the controlled module sends out at least one adjusting termination signal to obtain a specific optical parameter of the lighting device, wherein the adjusting termination signal adjusts the optical parameter of the lighting device to terminate changing; and

B323A: storing the specific optical parameter by the storage module.

According to another aspect of the present invention, there is provided a method for dimming a dimming device adapted to dim at least one optical parameter of a lighting device, comprising the steps of:

1000: generating at least one control signal by at least one control unit, wherein the control signal corresponds to the optical parameter;

2000: receiving and processing the control signal through at least one adjusting signal processing unit to obtain an adjusting signal, wherein the adjusting signal corresponds to the optical parameter; and

3000: and adjusting the lighting device through the adjusting signal.

Drawings

Fig. 1A and 1B are diagrams of practical applications of a direct-dimming lighting system according to a preferred embodiment of the present invention, wherein the direct-dimming lighting system comprises a control unit, a direct-dimming signal processing unit and a corresponding lighting device.

Fig. 2A to 2D are various embodiments of the control unit in the direct-dimming lighting system according to a preferred embodiment of the present invention.

Fig. 3A to 3B are implementation diagrams of the direct-modulation signal processing unit of the direct-modulation lighting system and the lighting device according to a preferred embodiment of the present invention, wherein the direct-modulation signal processing unit may be built in the lighting device or external to the lighting device.

Fig. 4 is a schematic diagram of the internal system configuration of the direct lighting system according to a preferred embodiment of the present invention.

Fig. 5A to 5B are schematic diagrams illustrating an internal structure of the control unit in the direct-dimming lighting system according to a preferred embodiment of the present invention, wherein the control unit can be implemented in a self-power-generating and external power-supplying mode.

Fig. 6 is a detailed schematic diagram of a signal receiving and sending unit in the direct-modulation signal processing unit in the direct-modulation lighting system according to a preferred embodiment of the present invention, wherein the signal transmission between the control unit and the direct-modulation signal processing unit can be performed in a wireless or wired manner.

Fig. 7A to 7D are detailed schematic diagrams of a signal processing unit in the direct-modulated lighting system according to a preferred embodiment of the present invention.

Fig. 8 is a detailed schematic diagram of the lighting device of the direct lighting system according to a preferred embodiment of the present invention, wherein the lighting device can also be implemented as a multi-type lamp.

Fig. 9A to 9B are two signal transmission modes of the signal transmission of the direct-dimming lighting system according to a preferred embodiment of the present invention.

Fig. 10 is a schematic structural diagram of the direct-dimming light-conditioning apparatus according to a preferred embodiment of the present invention.

Fig. 11A to 11B are schematic views of the direct-dimming illumination system according to a preferred embodiment of the present invention when selected in the direct-dimming mode.

Fig. 12 is a schematic diagram of the directly-adjusted lighting system according to a preferred embodiment of the present invention when the adjustable adjustment mode is selected.

Fig. 13 to 17 are schematic flow charts of the adjusting method of the direct-dimming lighting system according to a preferred embodiment of the present invention.

Fig. 18 to 21 are schematic flow charts of the direct-dimming method provided with the direct-dimming lighting device according to a preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and for simplicity in description, and do not indicate or imply that the referenced devices or components must be constructed and operated in a particular orientation and thus are not to be considered limiting.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

The invention provides a direct-modulation lighting system, wherein the direct-modulation lighting system comprises a direct-modulation light modulation device 1 and a corresponding lighting device 30, wherein the direct-modulation light modulation device 1 can be configured with different signal modulation programs to modulate the lighting device 30, so that the direct-modulation lighting system achieves different modulation effects. Specifically, the direct-dimming lighting device 1 can send different adjusting signals to adjust the lighting device, wherein the lighting device 30 is dimmed by receiving the adjusting signals.

Specifically, the direct-modulation light-adjusting device 1 further includes a control unit 10 and a direct-modulation signal processing unit 20, wherein the control unit 10 sends a control signal C to the direct-modulation signal processing unit 20, and the control signal C is processed by the direct-modulation signal processing unit 20 to obtain an adjustment signal a, wherein the adjustment signal a is used for adjusting the lighting device 30, and at this time, the lighting device 30 can be adjusted and controlled to achieve different light-emitting effects. It is worth mentioning that the adjustment signal a mainly adjusts the light color and luminosity of the lighting device 30.

As shown in fig. 1, fig. 1A and 1B are diagrams of practical applications of the direct-dimming lighting system according to the present invention, wherein the control unit 10 in the direct-dimming lighting system is implemented as a control switch, the direct-dimming signal processing unit 20 can be implemented as a receiving processing unit, and the direct-dimming signal processing unit 20 is built in the lighting device 30 to form an independent illuminator. Of course, the direct-modulation signal processing unit 20 can also be externally arranged on the illumination device 30 to control the illumination device independently, in this case, the illumination device 30 is implemented as a stand-alone illuminator. In the using process of the direct-modulation lighting system, the control unit 10 sends at least one control signal C to the direct-modulation signal processing unit 20, the control signal C is processed by the direct-modulation signal processing unit 20 and then converted into an adjustment signal a, the adjustment signal a reaches the lighting device 30, and the lighting device 30 receives an instruction of the adjustment signal a and makes a corresponding light-emitting response.

As shown in fig. 1A, the control unit 10 may be implemented as a passive controller, that is, the control unit 10 may implement control of the direct-modulation signal processing unit 20 and the lighting device 30 in a self-generating manner. At this time, the control unit 10 can be independently provided at various places without the power supply of an external device. For example, the control unit 10 may be placed anywhere in a room, and even the control unit 10 may be carried around by a user, in such a way as to facilitate the installation and use of the signal control unit 1.

It is further noted that, since the control unit 10 is implemented as a passive controller and the control unit 10 communicates with the directly modulated signal processing unit 20 in a signal transmission manner, the directly modulated lighting system can implement a dual-control or even multi-control operation manner. Specifically, when the direct-dimming lighting system is operated in a dual-control or even multi-control manner, the direct-dimming lighting system includes two or more control units 10, the direct-dimming signal processing unit 20, and the lighting device 30. In the present embodiment, the direct-dimming lighting system including two control units 10 is described as an example, and it should be understood by those skilled in the art that the present embodiment is only an embodiment and is not a limitation of the present invention.

At this time, the two control units 10 may control the same direct modulation signal processing unit 20 at the same time, or control different direct modulation signal processing units 20, and the direct modulation signal processing unit 20 receives the control signal C sent by the control unit 10 and then sends the adjustment signal a to adjust the lighting device 30. In this way, the user can place the control unit 10 at different positions, so as to dim the same lighting device 30 at different positions, thereby facilitating the use of the direct-dimming lighting system. Even, the user can carry the control unit 10 with him, and the control unit 10 sends the control signal C to the direct-modulation signal processing unit 20 within a certain signal range.

Of course, the control unit 10 is implemented as a passive controller, and the direct-dimming device has the advantages of being free of wiring, maintenance and battery power. This is not intended to be limiting and the control unit 10 may also be implemented as an active controller without affecting the inventive content of the present invention. A detailed structure of the control unit 10 will be disclosed in the following detailed description.

As shown in fig. 2, the control unit 10 may be implemented in various types of structures. The control unit 10 may for example be implemented as a seesaw switch, as shown in fig. 2A. The control unit 10 may also be implemented as a rotary switch, as shown in fig. 2B. The control unit 10 may also be implemented as a reciprocating switch, as shown in fig. 2C. The control unit 10 may also be implemented as an inductive switch, as shown in fig. 2D. I.e., the type structure of the control unit 10 is not limited, and when the control unit 10 is implemented as a different type of switch structure, a user may activate and close the control unit 10 in different ways without affecting the inventive concept of the present invention. In the present embodiment, the control unit 10 will be described by taking a seesaw switch and a reciprocating switch as examples.

As shown in fig. 3, the direct-tone signal processing unit 20 and the lighting device 30 may be used in combination in any manner, i.e., the combination of the direct-tone signal processing unit 20 and the lighting device 30 does not affect the inventive content of the present invention. For example, in an embodiment of the present invention, the direct-modulation signal processing unit 20 is built in the lighting device 30 to form an independent illuminator. In another embodiment of the present invention, the direct-modulation signal processing unit 20 is externally disposed on the illumination device 30. In other words, the light source portion in the direct-dimming lighting system may be implemented as an integrated lighting module, and may also be implemented as a combined lighting module of the direct-dimming signal processing unit 20 and the lighting device 30.

As shown in fig. 4, fig. 4 is a schematic diagram of the internal structure of the direct-dimming lighting system according to the present invention, wherein the control unit 10 includes a signal transmitting unit 11 and an energy supplying unit 12, wherein the direct-dimming signal processing unit 20 includes a signal transmitting and receiving unit 21 and a signal processing unit 22, and wherein the lighting device 30 includes a lighting unit 31. The signal sending unit 11 in the control unit 10 sends a control signal C, which is received by the signal sending and receiving unit 21 and processed by the signal processing unit 22, resulting in the adjustment signal a, which reaches the lighting unit 31 so that the lighting unit 31 reacts accordingly.

Wherein the control unit 10 can be implemented in a self-generating mode as well as in an externally powered mode, as shown in fig. 5A and 5B. When the control unit 10 is implemented in the self-power mode, i.e. when the control unit 10 is implemented as a passive controller, the power supply unit 12 includes a driving module 121 and a power generation module 122 connected to the driving module 121, wherein the driving module 121 drives the power generation module 122 to generate power.

Specifically, the control unit 10 is manufactured by micro energy technology, that is, the control unit 10 can generate energy by micro energy. That is, after the driving module 121 in the control unit 10 is driven, the driving module 121 can drive the capacity module 122 to generate capacity. The driving module 121 and the energy generating module 122 can be communicated through electromagnetic induction, high-frequency wireless, and mechanical piezoelectric. In other words, when the driving module 121 is driven, the driving module 121 may cause the energy generation module 122 to generate micro energy E electromagnetically, by radio waves, mechanically, or the like, and the micro energy E is suitable for supplying energy to the signal transmission unit 11. When the control unit 10 is implemented in a self-generating mode, the control unit 10 is produced in an environmentally friendly manner, and in this way the control unit 10 can be implemented as a passive controller. It should be understood by those skilled in the art that the self-generating modes of electromagnetic induction generation, high frequency wireless generation, and piezoelectric generation referred to in the present invention are embodiments, but not limiting.

It is worth mentioning that the driving manner of the driving module 121 is adapted to the type of the control unit 10. For example, when the control unit 10 is implemented as an inductive switch, the driving module 121 is implemented as an inductive driving, i.e., the user can inductively drive the driving module 121. For another example, when the control unit 10 is implemented as a reciprocating switch, the driving module 121 is implemented as a reciprocating drive.

Of course, the control unit 10 can also be implemented in an external power supply mode, in which case, the power supply unit 12 'in the control unit 10 includes an energy module 122', wherein the energy module 122 'can be implemented as a battery, i.e. the energy module 122' can directly supply power to the signal transmitting unit 11. In addition, the energy module 122 'can be implemented as an external power source, and in this case, external energy can reach the signal sending unit 11 through the transmission of the energy module 122'.

That is, the control unit 10 may be implemented as a passive controller or an active controller, and the type structure of the control unit 10 does not affect the inventive content of the present invention.

The signal transmitting unit 11 includes a signal transmitting module 111 therein, the signal transmitting module 111 further includes a coding component 1111 and a transmitting component 1112, wherein the coding component 1111 communicates with the energy supplying unit 12, the energy generated in the energy supplying unit 12 reaches the coding component 1111, the coding component 1111 can encode a special code M according to the driving signal response of the driving module 121, and the transmitting component 1111 converts the special code M into the control signal C to transmit to the direct modulation signal processing unit 20.

It should be noted that the signal transmitting unit 11 can be connected to the direct modulation signal processing unit 20 in a wireless or wired manner, wherein the transmitting component 1112 can emit various types of transmission signals such as infrared light, high frequency electromagnetic light, and the like, and the invention is not limited in this respect.

After the driving module 121 in the control unit 10 is triggered, the signal transmitting unit 12 transmits different control signals C according to different trigger signals, and the control signals C are transmitted to the direct-modulation signal processing unit 20 in a wireless or wired manner. At this time, the direct-modulation signal processing unit 20 receives the control signal C and reacts correspondingly to the control signal C.

In addition, the direct-adjusting signal processing unit 20 includes the signal receiving and sending unit 21 and the signal processing unit 22, the signal receiving and sending unit 21 sends out an intermediate signal Z after being triggered by the control signal C, and the intermediate signal Z is received by the signal processing unit 22 and then processed to obtain the adjusting signal a.

In addition, the signal receiving and sending unit 21 is in signal communication with the signal sending unit 11, and the signal sending unit 11 sends out the control signal C, where the control signal C is received by the signal receiving unit 21. As shown in fig. 6, the signaling unit 21 includes a receiving module 211, a decoding module 212, and a transmitting module 213, wherein the receiving module 211 receives the control signal C sent from the signal sending unit 11, the decoding module 212 decodes the control signal C received by the receiving module 211 to obtain the intermediate signal Z, and transmits the intermediate signal Z to the transmitting module 213, and the transmitting module 213 transmits the intermediate signal Z to the signal processing unit 22.

The encoding component 1111 of the signal transmitting module 111 is configured to be matched with the decoding module 212 of the signal receiving and transmitting unit 21, that is, the encoding component 1111 corresponds to the decoding module 212 one by one, the encoding component 1111 encodes and generates the control signal C, and the decoding module 212 can decode the control signal C and convert the control signal C into the intermediate signal Z that can be received by the direct modulation signal processing unit 20. Wherein the encoding components 1111 correspond to the decoding modules 212 in a one-to-one manner, so that the control signal C sent by the control device 10 can correspondingly control the direct modulation signal processing unit 20.

Of course, when the control unit 10 is in communication with the direct-modulation signal processing unit 20 in a wired manner, the control signal C is implemented as a wired signal, and the decoding module 212 in the signaling unit 21 decodes the control signal C to obtain the intermediate signal Z, and the intermediate signal Z is transmitted to the signal processing unit 22 to be processed as the modulation signal a.

As shown in fig. 7A to 7C, the signal processing unit 22 includes a processing module 221, wherein the processing module 221 can process the intermediate signal Z and convert the intermediate signal Z into an adjustment signal a, wherein the adjustment signal a adjusts the lighting device 30.

As shown in fig. 8, the lighting device 30 includes the lighting unit 31, and the lighting unit 31 can be adjusted by the adjustment signal a to emit a lighting signal. Wherein the lighting unit 31 further comprises at least one light emitting element 311, wherein the light emitting element 311 can be implemented as one or a combination of any light emitting elements, such as an LED lamp, a flexible lamp, an OLED lamp, a two-color lamp, and the like. It should be understood by those skilled in the art that the embodiment of the illumination device 30 in the present invention is illustrative only and not limiting.

The lighting device 30 is controlled by the adjusting signal a sent by the signal processing unit 20, and the optical parameters refer to the light intensity, the light temperature, the light color, and the like of the lighting unit 31, which is not limited in this respect.

It should be noted that the control unit 10 in the direct-dimming lighting system sends the control signal C, the control signal C is processed by the direct-dimming signal processing unit 20 to obtain the adjustment signal a, the adjustment signal a is used for controlling the lighting device 30, wherein the direct-dimming signal processing unit 20 can be set to different programs to obtain different adjustment signals a.

As shown in fig. 7A, the direct-adjusting signal processing unit 20 is set to a direct-adjusting mode, and at this time, the direct-adjusting device has a plurality of light brightness and color adjusting steps, each step is preset and stores the brightness value and the color value that the user is accustomed to, so that the user can quickly select the preset light brightness value through the direct-adjusting device according to the change of the ambient light, and in this way, the user can quickly and directly adjust the luminosity and the light color of the lighting device 30.

At this time, specific parameters are stored in the direct-modulation signal processing unit 20, and a user can directly call the specific parameters stored in the direct-modulation signal processing unit 20 through the control unit 10 and adjust the lighting device 30, that is, the user can quickly and conveniently adjust the lighting device 30 in a direct-modulation manner.

Specifically, the signal processing unit 22 in the direct-adjusting signal processing unit 20 further includes a storage module 222, wherein the storage module 222 stores specific optical parameters, and the optical parameters include the light intensity, the light temperature, the light color, and the like of the lighting unit 31. At this time, the storage module 222 communicates with the processing module 221, that is, the processing module 221 may call a specific optical parameter stored in the storage module 222 and process the specific optical parameter, so as to adjust the lighting device 30 with the specific optical parameter as the adjustment signal a.

Specifically, the driving module 121 in the control unit 10 of the direct-dimming lighting system includes at least one control key 1211, the user controls to drive the driving module 121 through the control key 1211, the driving module 121 controls the signal sending module 111 to send out the control signal C, and the control signal C is processed by the direct-dimming signal processing unit 20 to adjust the specific parameter in the storage module 222 and adjust the lighting device 30.

It should be noted that a plurality of different optical parameters may be stored in the storage module 222, and the control unit 10 may also include a plurality of different control keys 1211, wherein each control key 1211 corresponds to a specific optical parameter in the storage module 222, and of course, one control key 1211 may also correspond to a plurality of specific optical parameters in the storage module 222. The invention is not limited in this respect.

The control unit 10 includes three control keys 1211 for illustration, but not for limitation. At this time, the control keys 1211 in the control unit 10 may be respectively set to select different parameter values, such as three control keys 1211 in the control unit 10 corresponding to the illuminance of 10%, 50% and 100%, respectively, where the illuminance parameter is only used as an example. Correspondingly, the storage module 222 stores the illumination parameters of 10%, 50% and 100%, and at this time, the control key 1211 corresponds to a specific parameter in the storage module 222.

That is, when the user selects to control a specific control key 1211, the control key 1211 not only can drive the energy generating module 122 to generate energy, but also the control key 1211 can send a specific parameter to the signal sending unit 11, generate the control signal C and send the control signal C to the direct-modulation signal processing unit 20, and the direct-modulation signal processing unit 20 calls the corresponding optical parameter in the storage module 122 and converts the optical parameter into the intermediate signal Z to modulate the light of the lighting device 30.

The control keys 1211 of the control unit 10 may also be set to select different light colors, for example, the control keys 1211 of the control unit 10 are implemented with a red-yellow-blue hue, and the storage module 222 stores RGW parameters. The controller in the control unit 10 may also be implemented to select different color temperatures, such as the control key 1211 of the control unit 10 being implemented to cool and warm color temperatures, and the storage module 222 storing color temperature parameters accordingly.

Of course, the control key 1211 may also correspond to a plurality of optical parameters in the storage module 222, and the embodiment is not limited by the invention.

Specifically, the storage module 222 stores various parameters, such as light with different illumination intensities and light colors with different colors, and the user can directly invoke and select the parameters in the storage module 222 through the control unit 10 and directly react on the lighting device 30.

In addition, the optical parameters in the storage module 222 can be set by the user or by the manufacturer, which should not be construed as a limitation to the invention. In the direct-dimming lighting system, when the direct-dimming lighting device is implemented as a self-energy-producing unit, the driving module 121 can drive the energy-producing module 122 and trigger the signal sending unit 11 to send the control signal C. It is worth mentioning that the control signal C sent out by the signal sending unit 11 is related to the driving module 121. After being received by the signaling unit 21 in the direct-adjusting signal processing unit 20, the control signal C calls a specific optical parameter in the storage module 122, where the specific optical parameter is implemented as the intermediate signal Z, and the intermediate signal Z is processed by the signal processing unit 22 to obtain the adjusting signal a, which adjusts the lighting device 30 correspondingly, where the adjusting signal a is closely related to the storage module 122.

It is worth mentioning that, in order to facilitate the user's practicality, the direct-tuning parameters in the direct-tuning dimming system can be implemented as a preset mode. That is, the user may autonomously select to adjust the optical parameter of the lighting device 30, i.e., the optical parameter of the lighting device 30 may be varied during the adjustment and selected by the user. In other words, at this time, the optical parameters of the lighting device 30 are in a process of changing during the adjustment process, in which the user autonomously selects the selected optical parameters of the lighting device 30 required by the user, and the selected optical parameters can be stored as the direct-dimming optical parameters, so that the user can adjust the lighting device 30 in a direct-dimming manner after presettably selecting the required optical parameters.

At this time, the direct modulation signal processing unit 20 includes a controlled module 223, wherein the controlled module 223 is communicated with the illumination unit 31 and is controlled by the processing module 221, that is, after the controlled module 223 obtains the adjustment signal a processed by the processing module 221, the controlled module 223 can control the illumination unit 31 so that the working circuit 312 where the light emitting element 311 in the illumination unit 31 is located is changed, and further, the optical parameter of the light emitting element 311 is adjusted.

Specifically, the controlled module 223 is implemented as a light emitting device power supply, the controlled module 223 can control the working circuit 312 of the light emitting device 311, and the controlled module 223 is controlled by the processing module 221, wherein the controlled module 223 generates the adjustment signal a under the trigger of the processing module 221, wherein the adjustment signal a adjusts and controls the working circuit 312 of the light emitting device 311, and the current and the voltage of the working circuit 312 are changed accordingly, so that the optical parameter of the light emitting device 311 is changed. Of course, the adjustment signal a may also cause the light intensity and the light temperature of the light emitting element 311 to change.

Specifically, when the current of the operating circuit 312 becomes large, the light emitting element 311 becomes bright, in other words, the luminance of the light emitting element 311 can be adjusted by adjusting the current and the voltage of the operating circuit 312. Still alternatively, the light emitting element 311 emits red light when the current and voltage of the operating current 312 are adjusted to the red light standard, which is only an example, and the present invention is not limited in this respect.

The controlled module 223 further comprises a controlled end 2231, and an adjusting end 2232, wherein the controlled end 2231 is adapted to receive the intermediary signal of the processing module 221, and the adjusting end 2232 is adapted to emit the adjusting signal a. It is worth mentioning that the adjustment signal a is further divided into an adjustment start signal a1 and an adjustment stop signal a2, wherein the adjustment start signal a1 is adapted to start the adjustment of the lighting device 30 and the adjustment stop signal a2 is adapted to stop the adjustment of the lighting device 30.

Specifically, when the controlled module 223 is controlled to send out the adjustment start signal, the adjustment start signal causes the operating circuit 312 in the light emitting element 311 in the lighting device 30 to change, so as to start to change various optical parameters of the light emitting element 311, where the optical parameters of the light emitting element 311 include the light intensity, the light temperature, the light color, and the like of the light emitting element 311. When the optical parameter of the light emitting element 311 meets the user's usage criteria, the controlled module 223 sends the adjustment termination signal, which terminates the adjustment of the light emitting element 311, so that the optical parameter of the light emitting element 311 is stabilized at a specific value, and a selected optical parameter is obtained.

In addition, the controlled end 2231 of the controlled module 223 is in communication with the processing module 221, such that the controlled module 223 is controlled by the processing module 221. That is, the control unit 10 in the direct-dimming lighting system can accordingly emit a control start signal C1 and a control end signal C2 to adjust the operation state of the controlled module 223.

It should be noted that the driving module 121 in the control unit 10 can be used to drive the capacity module 122 to generate capacity, and at the same time, the signal sending unit 11 can be enabled to send the corresponding control signal C. The driving manner of the driving module 121 is not limited, that is, when the driving module 121 is implemented in various types of structures.

For example, the driving module 121 may be implemented as two control keys 1211, wherein a first control key 12111 is used for driving the signal transmitting unit 11 to transmit the control start signal C1, and a second control key 12112 is used for driving the signal transmitting unit 11 to transmit the control stop signal C2. Or the driving module 121 only comprises one control key 1211, wherein the control key 1211 can emit different signals to drive the signal transmitting unit 12 to emit different control signals C.

It is worth mentioning that the control manner of the control unit 10 is not limited. In the present embodiment, the control unit 10 may be preferably implemented as a reciprocating controller, wherein the reciprocating controller may issue two or more signals, thereby causing the signal sending unit 11 to issue the control start signal C1 and the control stop signal C2.

Specifically, the control unit 10 is controlled to send out the control start signal C1, and after the control start signal C1 is controlled by the processing module 221, the controlled terminal 223 is driven to send out the adjustment start signal a1, and the lighting device 30 starts adjustment change under the adjustment of the adjustment start signal a 1. When the lighting device 30 has reached the user's desired standard, the user can control the control unit 10 to issue a control termination signal C2, which C2 eventually triggers the controlled module 223 to issue the adjustment termination signal a2, in such a way that the final optical parameters of the lighting device 30 are determined.

When the direct-dimming lighting system is implemented as an adjustable lighting system, a variable control manner is implemented between the control unit 10 and the direct-dimming signal processing unit 20, that is, a user can control the direct-dimming signal processing unit 20 through the control unit 10, so that the lighting parameters of the lighting device 30 are autonomously selected, that is, the lighting effect of the lighting device 30 can be autonomously selected by the user.

In addition, the signal processing unit 22 may include both the storage module 222 and the controlled module 223, and at this time, the direct-dimming lighting system may perform direct-dimming adjustment and variable adjustment simultaneously, so as to facilitate the user.

Specifically, the storage module 222 is in communication with the processing module 221, and the controlled module 223 is also in communication with the processing module 221, and the processing module 221 can make different judgments according to different request signals to control the lighting device 30.

The storage module 222 stores specific optical parameters, which include the light intensity, the light temperature, the light color, and the like of the lighting unit 31. Wherein the storage module 222 is in communication with the processing module 221, i.e. the processing module 221 may call a specific optical parameter stored in the storage module 222 and adjust the lighting device 30 with the specific optical parameter as the adjustment signal a'.

Specifically, the driving module 121 in the control unit 10 of the direct-dimming lighting system includes at least one control key 1211, the user controls to drive the driving module 121 through the control key 1211, the driving module 121 controls the signal sending module 111 to send out the control signal C, and the control signal C is processed by the direct-dimming signal processing unit 20 to adjust the specific parameter in the storage module 222 and adjust the lighting device 30.

It should be noted that a plurality of different optical parameters may be stored in the storage module 222, and the control unit 10 may also include a plurality of different control keys 1211, wherein each control key 1211 may correspond to a specific optical parameter in the storage module 222, and of course, one control key 1211 may correspond to a plurality of specific optical parameters in the storage module 222. The invention is not limited in this respect.

At this time, the controlled module 223 is communicated with the illumination unit 31 and is controlled by the processing module 221, that is, after the controlled module 223 obtains the adjustment signal a processed by the processing module 221, the controlled module 223 can control the illumination unit 31 so that the working circuit 312 where the light emitting element 311 in the illumination unit 31 is located finds a change, thereby adjusting the optical parameter of the light emitting element 311.

Specifically, the controlled module 223 is implemented as a light emitting device power supply, the controlled module 223 can control the working circuit 312 of the light emitting device 311, and the controlled module 223 is controlled by the processing module 221, wherein the controlled module 223 generates the adjustment signal a under the trigger of the processing module 221, wherein the adjustment signal a adjusts and controls the working circuit 312 of the light emitting device 311, and the current and the voltage of the working circuit 312 are changed accordingly, so that the optical parameter of the light emitting device 311 is changed. Of course, the adjustment signal a ″ may also cause the light intensity and the light temperature of the light emitting element 311 to change.

Wherein the controlled module 223 further comprises a controlled end 2231, and an adjusting end 2232, wherein the controlled end 2231 is adapted to receive the intermediary signal of the processing module 221, and the adjusting end 2232 is adapted to emit the adjusting signal a. It is worth mentioning that the adjustment signal a can be divided into an adjustment start signal a1 and an adjustment stop signal a2, wherein the adjustment start signal a1 is adapted to start the adjustment of the lighting device 30 and the adjustment stop signal a2 is adapted to stop the adjustment of the lighting device 30.

Specifically, when the controlled module 223 is controlled to emit the adjustment start signal a1, the adjustment start signal a1 causes the operating circuit 312 in the light emitting element 311 in the lighting device 30 to change, so as to cause various optical parameters of the light emitting element 311 to start to change, where the optical parameters of the light emitting element 311 include the light intensity, the light temperature, the light color and the like of the light emitting element 311. When the optical parameter of the light emitting element 311 meets the user's usage criteria, the controlled module 223 sends out the adjustment termination signal A2, and the adjustment termination signal A2 terminates the adjustment of the light emitting element 311, so that the optical parameter of the light emitting element 311 is stabilized at a specific value.

In addition, the controlled end 2231 of the controlled module 223 is in communication with the processing module 221, such that the controlled module 223 is controlled by the processing module 221. That is, the control unit 10 in the direct-dimming lighting system can accordingly emit a control start signal C1 and a control end signal C2 to adjust the operation state of the controlled module 223.

As shown in fig. 10, the signal controllable and adjustable lighting system can adopt a stepless dimming manner to control the lighting device 30. Wherein the control unit 10 is preferably implemented as a reciprocating controller, i.e., the control unit 10 can be controlled to generate two or more control signals C, a control start signal C1 and a control end signal C2, it should be understood by those skilled in the art that the implementation type of the control unit 10 is only by way of example and not by way of limitation.

The signal processing unit 22 further comprises a determining module 225, wherein the determining module 225 is adapted to determine the time difference between the signals. Wherein the control start signal C1 and the control stop signal C2 are processed by the signaling unit 21 in the direct-adjusting signal processing unit 20 and then converted into the intermediate start signal C1 and the intermediate stop signal C2, respectively, and wherein the determining module 225 is adapted to determine the intermediate start signal C1 and the intermediate stop signal C2.

Wherein when the determining module 225 determines that the relationship between the intermediary start signal C1 and the intermediary stop signal C2 ″ satisfies the calling procedure, the processing module 221 invokes a specific parameter in the storage module 222, thereby causing the processing module 221 to issue the adjustment signal a of the calling formula. Wherein when the relationship between the medium start signal C1 and the medium stop signal C2 satisfies a variable procedure, the processing module 221 invokes the controlled module 223, and the controlled module 223 correspondingly adjusts the optical parameters of the lighting device 30.

In this embodiment, the determining module 225 determines the time difference between the medium start signal C1 and the medium stop signal C2. In the embodiment of the present invention, the control unit 10 is adapted to control the on and off of the lighting device 30 when the time between the medium start signal C1 and the medium stop signal C2 is less than an initial setting value.

When the intermediate start signal C and the intermediate stop signal C are greater than a predetermined value, the storage module 222 is called, and the control unit 10 can directly control the optical parameters of the lighting device 30 to a predetermined value.

When the time between the medium start signal C1 and the medium stop signal C2 is greater than an adjustment setting, such as 10 seconds, the controlled module 223 is activated to variably select the optical parameters of the lighting device 30.

When the control unit 10 is implemented as a reciprocating switch, it may be considered that the control unit 10 is pressed for the first time to drive the signal transmission unit 11 to transmit the control start signal C1, and when the user releases his hand, the control unit 10 returns to its original position, so that the signal transmission unit 11 transmits the control end signal C2, but this is merely an embodiment.

In addition, in order to make the direct-adjusting lighting system more service for users, the direct-adjusting lighting system can memorize optical parameters. At this time, the signal processing unit 22 is linked to the lighting device 30, in other words, the data in the storage module 222 can be set manually.

That is, when the controlled module 223 controls the lighting device 30 to obtain the adaptive optical parameters, the optical parameters of the lighting device 30 selected at this time can be stored in the storage module 222 for the next standby.

That is, the optical parameters stored in the storage module 222 can be set manually or by the manufacturer. After the optical parameters in the storage module 222 are manually set, the user can directly call the optical parameters needed by the user through the storage module 222, thereby facilitating the use of the user.

Further, in order to protect the safety of the usage of the direct-modulated signal processing unit 20, the direct-modulated signal processing unit 20 further includes a safety module 224, wherein the safety module 224 is linked with the processing module 221 and the signal receiving and sending unit 21, so that the direct-modulated signal processing unit 20 is used in a safe state.

The safety module 224 is implemented as a voltage reduction module, i.e. the safety module 224 can be adapted to provide the signal receiving and sending unit 21 and the signal processing unit 22 with voltages suitable for operation, thereby ensuring the safety of the usage of the direct-modulation signal processing unit 30.

In summary, the direct-adjusting signal processing unit 20 can be provided with different programs to adjust the lighting device 30 in different ways. The signal processing unit 22 in the direct-tone signal processing unit 20 is provided with the processing module 221, the storage module 222, the controlled module 223, the judgment module 225 and the safety module 224 as an example for a detailed summary description, but it should be understood by those skilled in the art that different programs may be provided in the direct-tone signal processing unit 20 to achieve different effects, and the embodiment of the present invention is not an influence of the present invention.

The signal receiving and sending unit 21 is connected with the signal processing unit 22 in a signal mode, and the signal receiving and sending unit 21 receives the control signal C from the control unit 10 and converts the control signal C into an intermediate signal Z which can be recognized by the signal processing unit 22.

The processing module 221 in the signal processing unit 22 is communicated with the signal receiving and sending unit 21, the storage module 222, the controlled module 223 and the determination module 225 are respectively communicated with the processing module 221, and the security module 224 is communicated with the processing module 221 and the signal receiving and sending unit 21 to provide security for the direct-modulation signal processing unit 20.

The determining module 225 can determine the intermediate signal Z sent from the signaling module 21, and when the determining module 225 determines that the intermediate signal Z is a signal for starting a calling procedure, the processing module 221 calls the optical parameter in the storage module 222 to control the lighting device 30.

When the determination module 225 determines that the intermediate signal Z sent from the signaling module 21 is a signal for adjusting a variable program, the processing module 221 controls the controlled module 223 to adjust the lighting device 30, so that the optical effect of the lighting device 30 reaches the parameters actually required by the user.

When the lighting device 30 obtains the optical parameters meeting the needs of the user under the control of the controlled module 223, the storage module 222 is linked to the lighting device 30, so that the optical parameters in the lighting device 30 can be stored in the storage module 222 for the subsequent use of the user.

It is of course worth mentioning that the controlled module 223 may also be adapted to the working state of the storage module 222, that is, the controlled module 223 is adapted to adjust the working circuit 312 of the light emitting element 311, and the controlled module 223 can adjust the light emitting element 311 according to the optical parameter set in the storage module 221.

The specific embodiments of the storage module 222 and the controlled module 223 have been described in detail in the above description, and are not described herein again. It should be understood by those skilled in the art that the signal processing unit 22 can adjust the illumination device 30 in a variety of ways without limiting the scope of the invention.

In addition, the present invention additionally provides an adjusting method of the direct-dimming lighting system, comprising the steps of:

1000: a control unit 10 sends out a control signal C;

2000: receiving and processing the control signal C by a dimming signal processing unit 20 to obtain an adjustment signal a, wherein the adjustment signal a corresponds to the light chromaticity of a lighting device 30; and

3000: an illumination device 30 is regulated by the regulating signal a.

It should be mentioned that the control unit 10 further comprises a signal transmitting unit 11 and an energy supplying unit 12, wherein the energy supplying unit 12 can be implemented in a self-generating energy and external energy supplying form, and the energy supplying unit 12 further comprises a driving module 121.

When the power supply unit 12 is implemented in the self-generating mode, the power supply unit further includes a power generation module 122, and the power generation module 122 can generate micro power according to the action of the driving module 121, and the micro power is used by the signal sending unit 11. It should be noted that the energy supply unit 12 can be implemented in various forms such as electromagnetic generation, high-frequency wireless generation, and mechanical piezoelectric generation without limitation.

In step 1000 of the adjusting method of the direct-dimming lighting system, the method may further include the following steps:

1100: receiving a starting signal;

1200: the activation signal is encoded for the control signal C by an encoding component 1111, wherein the control signals C correspond to the light color luminosity of a lighting device 30 one by one; and

1300: and sending the control signal C.

Wherein the control signal C may be implemented as one or a combination of a wireless signal or a wired signal.

In addition, the direct-modulation signal processing unit 20 includes a signal receiving and sending unit 21 and a signal processing unit 22, wherein the signal receiving and sending unit 21 is adapted to receive and send the control signal C to obtain the intermediate signal Z, and the signal processing unit 22 is adapted to process the intermediate signal Z.

That is, in step 2000 of the method for adjusting a direct-dimming lighting system, the method may further include the steps of:

2100: receiving and decoding the control signal C to obtain an intermediate signal Z; and

2200: the intermediate signal Z is processed to obtain the adjustment signal a, wherein the adjustment signal a corresponds to the light chromaticity of a lighting device 30.

Said step 2100 may in turn comprise the steps of:

2110: receiving the control signal C through a receiving module 211;

2120: decoding the control signal C by a decoding module 212 to obtain the intermediate signal Z; and

2130: the intermediate signal Z is sent to the signal processing unit 22.

It should be noted that the signal processing unit 22 includes a processing module 221, and the processing module 221 may be adapted to process the intermediate signal Z. In addition, the signal processing unit 22 may include at least one storage module 222, a controlled module 223, a determining module 225 and a security module 224, wherein the storage module 222, the controlled module 223 and the security module 224 may exist alone or in combination, and in this embodiment, the signal processing unit 22 including the storage module 222, the controlled module 223, the determining module 225 and the security module 224 is taken as an example for description, which is only an embodiment of the present invention.

Wherein the step 2200 further comprises the following steps:

2210: judging the intermediate signal Z to obtain a judgment result; and

2220: and selecting an applicable program according to the judgment result so as to obtain the adjusting signal A.

In step 2210, the signal processing unit 22 can select to enter one or a combination of a direct mode, a tunable mode and a recording mode by determining the intermediate signal.

When the signal processing unit 22 enters the direct mode, the step 2220 further includes the following steps:

2221: invoking a specific optical parameter in the storage module 222, according to the intermediate signal Z; and

2222: processing the specific optical parameter to obtain the adjusting signal A.

When the signal processing unit 22 enters the adjustable mode, the step 2220 further includes the following steps:

2221A: invoking the controlled module 223 to send out an adjustment start signal a 1; and

2222A: the controlled module 223 is stopped and an adjustment termination signal a2 is issued.

And correspondingly, the step 3000 includes the following steps:

3100: -starting a change of an optical parameter of said lighting device 30, in dependence of said adjustment start signal a 1; and

3200: the variation of the optical parameter of the lighting device 30 is stopped, depending on the adjustment termination signal a 2.

The adjusting method of the direct-adjusting lighting system further comprises the following steps;

3300: the specific optical parameters of the lighting device 30 are recorded.

In addition, the security module 224 is connected to the signal receiving and sending unit 21 and the signal processing unit 22, so as to provide security for the direct-adjusting signal processing unit 20, and it should be noted that the lighting device 30 includes a lighting unit 31, and the lighting unit 31 can be controlled by the adjusting signal a to emit a lighting signal. Wherein the lighting unit 31 further comprises at least one light emitting element 3111, wherein the light emitting element 3111 may be implemented as one or a combination of any light emitting elements, such as LED lamp, flexible lamp, OLED lamp, and two-color lamp, etc., the invention is not limited in this respect.

In addition, the present invention also provides an adjusting method of the lighting apparatus 30, wherein the lighting apparatus 30 comprises a direct-adjusting signal processing unit 20, wherein the adjusting method of the lighting apparatus 30 comprises the following steps:

1000': receiving a control signal C;

2000': processing the control signal C to obtain an adjustment signal a, wherein the adjustment signal a corresponds to a specific photometric color of the lighting device 30; and

3000': adjusting the lighting device 30 in accordance with the adjustment signal a.

The lighting device 30 comprises a lighting unit 31, and the lighting unit 31 can be regulated by the adjusting signal A to emit a lighting signal. Wherein the lighting unit 31 further comprises at least one light emitting element 3111, wherein the light emitting element 3111 can be implemented as one or a combination of any light emitting elements, such as LED lamp, flexible lamp, OLED lamp, and two-color lamp, etc., the invention is not limited in this respect.

The direct modulation signal processing unit 20 includes a signal receiving and sending unit 21 and a signal processing unit 22. Wherein the signal receiving and sending unit 21 receives the control signal C from the outer segment, and the signal processing unit 22 processes the control signal C to obtain the adjustment signal a.

The control signal C may be implemented as one or a combination of a wireless signal or a wired signal.

That is, in step 1000' of the adjusting method of the lighting device 30, the method further includes the steps of:

1100': receiving and decoding the control signal C to obtain an intermediate signal Z; and

1200': the intermediate signal Z is sent to the signal processing unit 22.

Wherein the step 1100' may in turn comprise the steps of:

1110': receiving the control signal C through a receiving module 211;

1120': decoding the control signal C by a decoding module 212 to obtain the intermediate signal Z; and

1130': the intermediate signal Z is sent to the signal processing unit 22.

It should be noted that the signal processing unit 22 includes a processing module 221, and the processing module 221 may be adapted to process the intermediate signal Z. In addition, the signal processing unit 22 may include at least one storage module 222, a controlled module 223, a determining module 225 and a security module 224, wherein the storage module 222, the controlled module 223 and the security module 224 may exist alone or in combination, and in this embodiment, the signal processing unit 22 including the storage module 222, the controlled module 223, the determining module 225 and the security module 224 is taken as an example for description, but this is only an embodiment of the present invention.

Wherein the step 2000' further comprises the following steps:

2100': judging the control signal C to obtain a judgment result; and

2200': and selecting an applicable program according to the judgment result so as to obtain the adjusting signal A.

In step 2210, the signal processing unit 22 determines the control signal C to select one or a combination of a direct mode, a tunable mode, and a recording mode.

When the signal processing unit 22 enters the direct mode, the step 2220' further includes the following steps:

2221': invoking a specific optical parameter in the storage module 222, according to the control signal C; and

2222': processing the specific optical parameter to obtain the adjusting signal A.

When the signal processing unit 22 enters the adjustable mode, the step 2220' further includes the following steps:

2221A': invoking the controlled module 223 to send out an adjustment start signal a 1; and

2222A': the controlled module 223 is stopped and an adjustment termination signal a2 is issued.

And correspondingly, the step 3000 further comprises the steps of:

3100': -starting a change of an optical parameter of said lighting device 30, in dependence of said adjustment start signal a 1; and

3200': the variation of the optical parameter of the lighting device 30 is stopped, depending on the adjustment termination signal a 2.

Wherein the adjusting method of the direct-adjusting lighting system further comprises the following steps;

3300': the specific optical parameters of the lighting device 30 are recorded.

In addition, the security module 224 is connected to the signal receiving and sending unit 21 and the signal processing unit 22, so as to provide security for the direct modulation signal processing unit 20. It should be noted that the lighting device 30 includes a lighting unit 31, and the lighting unit 31 can be controlled by the adjusting signal a to emit a lighting signal. Wherein the lighting unit 31 further comprises at least one light emitting element 3111, wherein the light emitting element 3111 can be implemented as one or a combination of any light emitting elements, such as LED lamp, flexible lamp, OLED lamp, and two-color lamp, etc., the invention is not limited in this respect.

In summary, the direct-dimming lighting system of the present invention is characterized in that the direct-dimming lighting apparatus 1 is applied to the lighting apparatus 30, so that the lighting apparatus 30 is in a convenient control manner.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (54)

1. A direct-dimming light-modulating device adapted to modulate optical parameters of at least one lighting device, the direct-dimming light-modulating device comprising:

at least one control unit, wherein the control unit is in a self-energy-generating mode, wherein the control unit comprises at least one signal transmitting unit, wherein the signal transmitting unit can generate at least one control start signal or at least one control end signal, wherein the control start signal or the control end signal respectively corresponds to the optical parameters of the lighting device, wherein the control unit comprises at least one driving module and at least one energy generating module, wherein the driving module drives the energy generating module to generate energy, and the driving module and the energy generating module jointly form at least one energy supply unit, wherein the energy supply unit supplies energy to the direct-modulation dimming device, and the energy supply unit is electromagnetic induction electricity generation or mechanical piezoelectric electricity generation; wherein, when the driving module is driven, the driving module enables the energy generation module to generate micro energy, and the micro energy is suitable for providing energy for the signal transmission unit; and

at least one direct-modulation signal processing unit, wherein the direct-modulation signal processing unit is controlled by the control unit, wherein the direct-modulation signal processing unit comprises at least one signal receiving and sending unit and at least one signal processing unit, wherein the signal processing unit comprises at least one storage module, the storage module stores the optical parameters of the lighting device, the signal receiving and sending unit respectively and correspondingly receives the control starting signal or the control ending signal so as to respectively generate an intermediate signal and transmit the intermediate signal to the signal processing unit, the signal processing unit respectively and correspondingly sends an adjustment starting signal or an adjustment ending signal so as to form a variable modulation and control of the lighting device, the signal sending unit comprises an encoding component and a sending component, and the encoding component is communicated with the energy supply unit, the energy generated by the energy supply unit reaches the coding component, the coding component encodes a special code aiming at a driving signal response of the driving module, the sending component converts the special code into a control signal and sends the control signal to the direct modulation signal processing unit, the direct modulation signal processing unit comprises a receiving module, a decoding module and a transmitting module, the receiving module receives the control signal sent by the signal sending unit, the decoding module decodes the control signal received by the receiving module and obtains the intermediary signal, the intermediary signal is transmitted to the transmitting module, the transmitting module transmits the intermediary signal to the signal processing unit, the direct modulation signal processing unit comprises a controlled module, the controlled module is communicated with the lighting device, and when the controlled module is controlled to send the adjustment starting signal, the adjustment start signal causes the working circuit of the light-emitting element of the lighting device to change, so that various optical parameters of the light-emitting element start to change, when the optical parameters of the light-emitting element meet the use standard of a user, the controlled module sends out the adjustment stop signal, and the adjustment stop signal stops adjusting the light-emitting element, so that the optical parameters of the light-emitting element are stabilized at a specific value to obtain a selected optical parameter.

2. The direct dimming device according to claim 1, wherein the driving module comprises at least one control key, wherein the control key generates the control start signal or the control end signal in a one-to-one correspondence.

3. The direct-dimming light-conditioning device according to claim 2, wherein the control unit comprises at least one energy module, wherein the energy module and the driving module together form at least one energy supply unit, wherein the energy supply unit supplies energy to the direct-dimming light-conditioning device.

4. The direct-dimming device of claim 2, wherein the optical parameter of the lighting device is selected from one or a combination of a light brightness parameter and a light color parameter of the lighting device.

5. The direct-dimming apparatus of claim 2, wherein the signal processing unit comprises at least one processing module, wherein the storage module is communicatively connected to the processing module, and the processing module receives the intermediate signal and calls the optical parameter corresponding to the storage module to obtain the adjustment start signal or the adjustment stop signal.

6. The direct-dimming device of claim 5, wherein the controlled module is disposed corresponding to the processing module, the processing module controls the controlled module to change between a regulation state and a non-regulation state, and the controlled module regulates the operating circuit of the lighting device when the controlled module is in the regulation state.

7. The direct-dimming device of claim 6, wherein the controlled module under the control of the driving module sends out at least one of the start-of-adjustment signals and at least one of the end-of-adjustment signals, wherein the start-of-adjustment signals adjust the start of the change of the optical parameter of the lighting device, and the end-of-adjustment signals adjust the end of the change of the optical parameter of the lighting device and obtain at least one preselected optical parameter.

8. The direct dimming device of claim 7, wherein said controlled module is in communication with said storage module, said storage module storing said preselected optical parameters obtained by said controlled module.

9. The direct-dimming device of any of claims 6-8, wherein said signal processing unit comprises at least one judging module, wherein said judging module is communicatively connected to said processing module, said judging module judges and controls said adjusted state and said un-adjusted state of said controlled module.

10. The direct-dimming lighting device according to any one of claims 2-8, wherein the signal processing unit comprises at least one safety module, wherein the safety module is connected to the signal receiving and sending unit and the signal processing unit to stabilize the working state of the direct-dimming signal processing unit.

11. The direct-dimming device of claim 9, wherein the signal processing unit comprises at least one safety module, wherein the safety module is connected to the signal receiving and sending unit and the signal processing unit to stabilize the operating state of the direct-dimming signal processing unit.

12. The direct dimming device of any one of claims 2-8, wherein said encoding component encodes said control start signal or said control stop signal, and said decoding module decodes said control start signal or said control stop signal to obtain said opposite intermediate signal.

13. The direct dimming device of claim 12, wherein the encoding components and the encoding procedures between the decoding modules are in one-to-one correspondence.

14. The direct-modulation light-adjusting device according to any one of claims 2-8, wherein the control unit and the direct-modulation signal processing unit can be communicated with each other by one or a combination of wireless or wired methods.

15. The direct dimming device of claim 2, wherein the driving module is in communication with the power generation module by one or a combination of electromagnetic power generation, high frequency wireless power generation and mechanical piezoelectric power generation.

16. The direct dimming device according to any of claims 2-8, wherein the control unit can be implemented as one or a combination of a rocker switch, a reciprocating switch or an inductive switch.

17. A direct-modulated dimming lighting system, comprising:

at least one lighting device, wherein the lighting device comprises at least one lighting unit, at least one optical parameter of which is adjusted;

at least one control unit, wherein the control unit comprises at least one signal sending unit, wherein the signal sending unit can generate at least one control start signal or at least one control end signal, wherein the control start signal or the control end signal respectively corresponds to the optical parameters of the lighting device, wherein the control unit comprises at least one driving module and at least one energy generating module, wherein the driving module drives the energy generating module to generate energy, and the driving module and the energy generating module jointly form at least one energy supply unit, wherein the energy supply unit supplies energy to the direct-modulation light-modulating device; and

at least one direct-modulation signal processing unit, wherein the direct-modulation signal processing unit is controlled by the control unit, wherein the direct-modulation signal processing unit comprises at least one signal receiving and sending unit and at least one signal processing unit, wherein the signal processing unit comprises at least one storage module, the storage module stores the optical parameters of the lighting device, the signal receiving and sending unit respectively and correspondingly receives the control starting signal or the control ending signal so as to respectively generate an intermediate signal and transmit the intermediate signal to the signal processing unit, the signal processing unit respectively and correspondingly sends an adjustment starting signal or an adjustment ending signal so as to form a variable modulation and control of the lighting device, the signal sending unit comprises an encoding component and a sending component, and the encoding component is communicated with the energy supply unit, the energy generated by the energy supply unit reaches the coding component, the coding component encodes a special code aiming at a driving signal response of the driving module, the sending component converts the special code into a control signal and sends the control signal to the direct modulation signal processing unit, the direct modulation signal processing unit comprises a receiving module, a decoding module and a transmitting module, the receiving module receives the control signal sent by the signal sending unit, the decoding module decodes the control signal received by the receiving module and obtains the intermediary signal, the intermediary signal is transmitted to the transmitting module, the transmitting module transmits the intermediary signal to the signal processing unit, the direct modulation signal processing unit comprises a controlled module, the controlled module is communicated with the lighting unit, and when the controlled module is controlled to send the adjustment starting signal, the adjustment start signal causes the working circuit of the light-emitting element of the lighting device to change, so that various optical parameters of the light-emitting element start to change, when the optical parameters of the light-emitting element meet the use standard of a user, the controlled module sends out the adjustment stop signal, and the adjustment stop signal stops adjusting the light-emitting element, so that the optical parameters of the light-emitting element are stabilized at a specific value to obtain a selected optical parameter.

18. The direct dimming lighting system according to claim 17, wherein the control unit commonly controls a plurality of the direct dimming signal processing units, or a plurality of the control units controls the direct dimming signal processing units.

19. The direct-dimming lighting system of claim 18, wherein the direct-dimming signal processing unit is built into the lighting device.

20. The direct-dimming lighting system of claim 18, wherein the direct-dimming signal processing unit is in independent communication with the lighting device.

21. The direct dimming lighting system of claim 18, wherein the driving module comprises at least one control key, wherein the control key generates the control start signal or the control end signal in a one-to-one correspondence.

22. The direct dimming lighting system of claim 21, wherein the control unit utilizes micro energy to generate power.

23. The direct dimming lighting system of claim 21, wherein the optical parameter of the lighting device is selected from one or a combination of a light color parameter and a light color parameter of the lighting device.

24. The direct-dimming lighting system of claim 21, wherein the signal processing unit comprises a processing module, wherein the memory module is communicatively coupled to the processing module, and the processing module receives the intermediate signal and invokes the corresponding optical parameter in the memory module to obtain the adjustment start signal or the adjustment stop signal.

25. The direct dimming lighting system of claim 24, wherein the controlled module is disposed in correspondence with the processing module, the processing module controls the controlled module to change between an adjustment state and a non-adjustment state, and the controlled module changes the operating circuit of the lighting device when the controlled module is in the adjustment state.

26. The direct-dimming lighting system of claim 25, wherein the controlled module under control of the driving module sends out at least one of the adjustment start signal and at least one of the adjustment end signal, wherein the adjustment start signal adjusts an optical parameter of the lighting device to start changing, and the adjustment end signal adjusts the optical parameter of the lighting device to end changing to obtain at least one preselected optical parameter.

27. The direct dimming lighting system of claim 26, wherein the controlled module is in communication with the storage module, the storage module storing the preselected optical parameter.

28. The direct-dimming lighting system of any of claims 25-27, wherein the signal processing unit comprises at least one judging module, wherein the judging module is communicatively connected to the processing module, and the judging module judges and controls the adjusted state and the un-adjusted state of the controlled module.

29. The direct-dimming lighting system according to any one of claims 21-27, wherein the signal processing unit comprises at least one safety module, wherein the safety module is connected to the signal receiving and sending unit and the signal processing unit to stabilize the operation state of the direct-dimming signal processing unit.

30. The direct dimming lighting system of any of claims 21-27, wherein the encoding component encodes the control start signal or the control stop signal, and the decoding module decodes the control start signal or the control stop signal as opposed to the intermediate signal.

31. The direct dimming lighting system of claim 30, wherein the encoding components and the decoding modules have a one-to-one correspondence in encoding procedures.

32. The direct-dimming lighting system according to any one of claims 21-27, wherein the control unit and the direct-dimming signal processing unit are in communication with each other in one or a combination of wireless or wired manner.

33. The direct dimming lighting system of claim 21, wherein the driving module is in communication with the energy generation module by one or a combination of electromagnetic generation, high frequency wireless generation, and mechanical piezoelectric generation.

34. The direct dimming lighting system of any of claims 21-27, wherein the control unit is selected from one or a combination of a rocker switch, a reciprocating switch, or an inductive switch.

35. A luminaire, conditioned by at least one control start signal or at least one control end signal, said control start signal and said control end signal being generated by a signaling unit of a control unit, characterized by comprising:

at least one lighting device, wherein the lighting device comprises at least one lighting unit, at least one optical parameter of the lighting unit is adjusted, wherein the control unit comprises at least one driving module and at least one energy generation module, wherein the driving module drives the energy generation module to generate energy, and the driving module and the energy generation module jointly form at least one energy supply unit, wherein the energy supply unit supplies energy to the direct-modulation light-modulating device; and

at least one direct-modulation signal processing unit, wherein the direct-modulation signal processing unit includes at least one signal receiving and sending unit and at least one signal processing unit, wherein the signal processing unit includes at least one storage module, the storage module stores the optical parameters of the lighting device, the signal receiving and sending unit respectively and correspondingly receives the control start signal or the control end signal to respectively generate an intermediate signal and transmit the intermediate signal to the signal processing unit, the signal processing unit respectively and correspondingly sends an adjustment start signal or an adjustment end signal to form a variable modulation and control of the lighting device, wherein the signal processing unit includes at least one processing module and at least one controlled module, the controlled module is arranged corresponding to the processing module, and the processing module controls the controlled module to change between a modulation state and a non-modulation state, when the controlled module is in the adjusting state, the controlled module changes a working circuit of the lighting device, the signal sending unit comprises an encoding component and a sending component, the encoding component is communicated with the energy supply unit, the energy generated by the energy supply unit reaches the encoding component, the encoding component encodes a special code according to a driving signal response of the driving module, the sending component converts the special code into a control signal and sends the control signal to the direct modulation signal processing unit, the direct modulation signal processing unit comprises a receiving module, a decoding module and a transmitting module, the receiving module receives the control signal sent by the signal sending unit, the decoding module decodes the control signal received by the receiving module, obtains the intermediate signal and transmits the intermediate signal to the transmitting module, the transmission module transmits the intermediate signal to the signal processing unit, the controlled module is communicated with the lighting unit, when the controlled module is controlled to send out the adjustment starting signal, the adjustment starting signal enables the working circuit of the light-emitting element of the lighting device to change, so that various optical parameters of the light-emitting element start to change, when the optical parameters of the light-emitting element meet the use standard of a user, the controlled module sends out the adjustment ending signal, and the adjustment ending signal ends the adjustment of the light-emitting element, so that the optical parameters of the light-emitting element are stabilized at a specific value, and a selected optical parameter is obtained.

36. The luminaire of claim 35, wherein the direct-tone signal processing unit is built into the illumination device.

37. The luminaire of claim 35, wherein the optical parameter of the lighting device is selected from one or a combination of a light brightness parameter and a light color parameter of the lighting device.

38. The luminaire of claim 35, wherein the memory module is communicatively coupled to the processing module, the processing module receiving the intermediary signal and invoking the corresponding optical parameter in the memory module resulting in the adjustment start signal or the adjustment stop signal.

39. The luminaire of claim 35, said controlled module under control of said drive module issuing at least one of said adjustment start signal, which adjusts a start of change in an optical parameter of said illumination device, and at least one of said adjustment stop signal, which adjusts an end of change in said optical parameter of said illumination device to obtain at least one preselected optical parameter.

40. The luminaire of claim 39, wherein the controlled module is in communication with the storage module, the storage module storing the preselected optical parameter.

41. A luminaire according to any one of claims 39-40, wherein said signal processing unit comprises at least one judging module, wherein said judging module is communicatively connected to said processing module, said judging module judging said regulated state and said unregulated state controlling said controlled module.

42. A luminaire according to any one of claims 39-40, wherein said signal processing unit comprises at least one security module, wherein said security module is connected to said signal receiving and transmitting unit and said signal processing unit for stabilizing the operating state of said direct modulation signal processing unit.

43. The luminaire of any of claims 39-40, wherein said encoding component encodes said control start signal or said control stop signal, and said decoding module decodes said control start signal or said control stop signal as opposed to said intermediate signal.

44. The luminaire of claim 43, wherein the encoding procedures between the encoding component and the decoding module are in one-to-one correspondence.

45. A dimming method of a direct dimming lighting system, adapted to adjust optical parameters of at least one lighting device, comprising the steps of:

a: sending at least one control starting signal or at least one control ending signal through at least one control unit;

b: at least one adjusting signal processing unit relatively receives and processes the control starting signal or the control ending signal to relatively obtain at least one adjusting starting signal or at least one adjusting ending signal, wherein at least one processing module controls at least one controlled module to change between an adjusting state and a non-adjusting state; and

c: adjusting the lighting device by the adjustment start signal or the adjustment stop signal, providing energy to an encoding component by an energy supply unit, the encoding component encoding a special code in response to a driving signal of a driving module, converting the special code into a control signal by a transmitting component and transmitting the control signal to the direct modulation signal processing unit, receiving the control signal transmitted by the signal transmitting unit by a receiving module of the direct modulation signal processing unit, decoding the control signal received by the receiving module by a decoding module of the direct modulation signal processing unit to obtain an intermediate signal, transmitting the intermediate signal to a transmitting module of the direct modulation signal processing unit, transmitting the intermediate signal to the signal processing unit by the transmitting module, and communicating the controlled module with the lighting device, when the controlled module is controlled to send out the adjustment starting signal, the adjustment starting signal enables the working circuit of the light-emitting element of the lighting device to be changed, so that various optical parameters of the light-emitting element start to change, when the optical parameters of the light-emitting element meet the use standard of a user, the controlled module sends out the adjustment stopping signal, the adjustment stopping signal stops adjusting the light-emitting element, so that the optical parameters of the light-emitting element are stabilized at a specific value, and a selected optical parameter is obtained.

46. The method of dimming a direct dimming lighting system of claim 45, wherein the optical parameter of the lighting device is selected from one or a combination of a light intensity parameter and a light color parameter of the lighting device.

47. The method of dimming a direct-dimming lighting system of claim 46, wherein the step A further comprises the steps of:

a1: receiving at least one starting signal through at least one driving module;

a2: the starting signal is coded into the control starting signal or the control ending signal through the coding component; and

a3: and relatively sending the control starting signal or the control ending signal to a direct modulation signal processing unit.

48. The dimming method of a direct-dimming lighting system of claim 46, wherein the step B further comprises the steps of:

b1: relatively receiving the control start signal or the control termination signal;

b2: decoding the control start signal or the control stop signal into at least one intermediate signal by the decoding module; and

b3: and processing the intermediate signal to obtain the adjustment starting signal or the adjustment ending signal.

49. The dimming method of a direct-dimming lighting system of claim 47, wherein the step B further comprises the steps of:

b1: relatively receiving the control start signal or the control termination signal;

b2: decoding the control start signal or the control stop signal into at least one intermediate signal, and passing through at least one decoding module; and

b3: and processing the intermediate signal to obtain the adjustment starting signal or the adjustment ending signal.

50. The dimming method of a direct-dimming lighting system of claim 49, wherein the encoding procedures between the encoding component and the decoding module are in one-to-one correspondence.

51. The dimming method of a direct-dimming lighting system according to claim 49 or 50, wherein the step B3 further comprises the steps of:

b31: judging the intermediary signal through at least one judging module to obtain at least one judging result; and

b32: and selecting a module according to the judgment result to obtain the adjustment starting signal or the adjustment ending signal.

52. The dimming method of a direct-dimming lighting system of claim 51, wherein the step B32 further comprises the steps of:

b321: calling a specific optical parameter in a storage module according to the intermediate signal; and

b322: and processing the specific optical parameter to obtain the adjustment starting signal or the adjustment ending signal.

53. The dimming method of a direct-dimming lighting system of claim 51, wherein the step B32 further comprises the steps of:

B321A: calling the controlled module to send out at least one adjusting starting signal, wherein the adjusting starting signal adjusts the optical parameters of the lighting device to start changing;

B322A: the controlled module sends out at least one adjusting termination signal to obtain a specific optical parameter of the lighting device, wherein the adjusting termination signal adjusts the optical parameter of the lighting device to terminate changing; and

B323A: the specific optical parameter is stored by a storage module.

54. A dimming method of a direct dimming device is suitable for adjusting optical parameters of at least one lighting device, and comprises the following steps:

1000: generating at least one control start signal or at least one control stop signal by at least one control unit, wherein the control start signal or the control stop signal corresponds to the optical parameter;

2000: the control starting signal or the control ending signal is relatively received and processed through at least one direct modulation signal processing unit, so that at least one modulation starting signal or at least one modulation ending signal is relatively obtained, wherein the modulation starting signal or the modulation ending signal respectively corresponds to the optical parameters, and at least one processing module controls at least one controlled module to change between a modulation state and a non-modulation state; and

3000: the lighting device is respectively adjusted through the adjustment starting signal or the adjustment ending signal, an energy supply unit supplies energy to an encoding assembly, the encoding assembly encodes a special code aiming at a driving signal of a driving module, a sending assembly converts the special code into a control signal and sends the control signal to the direct modulation signal processing unit, a receiving module of the direct modulation signal processing unit receives the control signal sent by the signal sending unit, a decoding module of the direct modulation signal processing unit decodes the control signal received by the receiving module to obtain an intermediate signal, the intermediate signal is transmitted to a transmitting module of the direct modulation signal processing unit, the transmitting module transmits the intermediate signal to the signal processing unit, and the controlled module is communicated with the lighting device, when the controlled module is controlled to send out the adjustment starting signal, the adjustment starting signal enables the working circuit of the light-emitting element of the lighting device to be changed, so that various optical parameters of the light-emitting element start to change, when the optical parameters of the light-emitting element meet the use standard of a user, the controlled module sends out the adjustment stopping signal, the adjustment stopping signal stops adjusting the light-emitting element, so that the optical parameters of the light-emitting element are stabilized at a specific value, and a selected optical parameter is obtained.

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