CN210202156U - Non-stroboscopic photosensitive illuminating lamp - Google Patents

Abstract

The utility model provides a no stroboscopic sensitive illumination lamps and lanterns, including a control unit, a light acquisition sensor to and an at least light, wherein the control unit communicably connects the light acquisition sensor, the control unit controllable connection in the light, wherein the light acquisition sensor provides ambient light data, wherein according to the ambient light data of gathering, the control unit control the working method of light. The photosensitive illuminating lamp can continuously emit light to provide illumination, so that both the light-emitting effect and the detection effectiveness are considered.

Description

Non-stroboscopic photosensitive illuminating lamp

Technical Field

The utility model relates to a luminous illumination electron device especially relates to a device based on external light sense and control and lamp of illumination.

Background

The lighting lamp is produced by people because light rays are not bright enough in production and life. In the case of insufficient light, the human eye illuminates the light to provide illumination so that the world becomes visible. And because of the popularization of alternating current, the lamp is basically powered by current with frequency, so the phenomenon of flash frequency of the lamp is also common. That is, the lamp will flash at a frequency that is not recognizable to human eyes. Although imperceptible, such flickering illumination is harmful to the human eye for long periods of time.

The existing lamp provides a light emitting mode without flash frequency, and particularly in an LED lamp, the flash frequency problem can be effectively avoided through the design of a driving circuit and a voltage stabilizing circuit. The existing lamp can continuously emit light and continuously provide illumination without any time gap of non-light emitting. In addition, some existing lamps do not intentionally solve the problem of flicker frequency, but detect the ambient light environment by using the non-luminous gap in the flicker frequency, and automatically adjust the luminous effect according to the external environment.

If the existing lamp wants to keep working without flash frequency and also wants to detect the environment of ambient light, the existing lamp can only detect the environment of light emission. Ambient light is difficult to separate and detect while maintaining the illumination. The adjustment of the lighting of the lamp by using the detection data is difficult, and the required algorithm is complex. If the light is turned off for detection, no continuous illumination is provided, sacrificing the visible world. The inability to provide continuous lighting certainly fails to meet the needs of productive life and is an unintelligent and unwelcome solution. In addition, in the existing lamp, the sensor is generally arranged around the lamp, and the light emitting range of the lamp is detected by the sensor to have a certain gap. The adjustment using the surrounding detection data also faces complex algorithms.

Some existing light fixtures may use a flicker-free design to allow a user to manually adjust the brightness or to preset the change in brightness. This requires manual adjustment, adding to the user's hassle. The adjusted brightness is also not suitable for meeting the ambient light environment or the actual needs of the user.

Preferably, the human eye is harmlessly treated, and the flicker-free effect is required. Preferably, non-luminescence detection is considered, so that detection in strobe is required. The two contradiction aspects which cannot be solved by the existing lamp are achieved.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main advantage lies in providing a no stroboscopic light-sensitive illumination lamps and lanterns, wherein no stroboscopic light-sensitive illumination lamps and lanterns can provide the continuous illumination that is adapted to ambient light according to ambient light, compromise luminous effect and detection validity.

Another advantage of the present invention is to provide a no stroboscopic light-sensitive lighting fixture, wherein the light-sensitive control device provides direct current output in order to pause the light-sensitive mode that detects, so that no stroboscopic light-sensitive lighting fixture can illuminate with no stroboscopic mode, and the protection is healthy with the eye.

Another advantage of the present invention is to provide a non-stroboscopic illumination lamp, wherein the non-stroboscopic illumination lamp itself emits light which cannot be detected by the light sensing control device, and then the authenticity and reliability of the detection result are improved.

Another advantage of the present invention is to provide a non-stroboscopic light-sensitive lighting fixture, wherein the sensing control device detects the ambient light with the mode of pause current output, then the light-emitting of non-stroboscopic light-sensitive lighting fixture self can not be detected by the sensing control device.

Another advantage of the utility model is that a no stroboscopic photosensitive lighting lamps and lanterns is provided, sensitization controlling means adjusts to ambient light condition no stroboscopic photosensitive lighting lamps and lanterns luminous, improve the regulation suitability.

Another advantage of the present invention is to provide a non-stroboscopic illumination device, the light emission of the non-stroboscopic illumination device is periodically adjusted to adapt to the time lapse and adjust the light emission.

Another advantage of the present invention is to provide a non-stroboscopic light-sensitive lighting fixture, the light-sensitive method does not cause stroboscopic lighting, thereby ensuring the persistence of lighting and eye health for maintenance.

Another advantage of the present invention is to provide a non-stroboscopic illumination lamp, which evaluates the external environment according to the light emitted by the adjustment, reminds the user or adaptively adjusts the light emission to properly change the external environment.

Another advantage of the present invention is to provide a non-stroboscopic illumination device, which can record the relationship between light emission and time, and can use the record to adjust the light emission according to the time without detection.

Another advantage of the present invention is to provide a non-stroboscopic light-sensitive lighting fixture, the recorded light emission and time correlation are associated with external information, such as external weather information, so as to adopt the recorded light emission and time correlation to emit light according to the time adjustment under the condition that the external information is matched.

Another advantage of the utility model is that a do not have stroboscopic sensitization lighting fixture is provided, the luminous and time interrelationship of record can be by a plurality of do not have stroboscopic sensitization lighting fixture work and use, promote whole lighting environment's continuation and health.

The other advantages and features of the invention will be fully apparent from the following detailed description and realized by means of the instruments and combinations particularly pointed out in the appended claims.

According to an aspect of the utility model, the utility model discloses a further a no stroboscopic lighting fixture is provided, include:

the lighting system comprises a control unit, a light collection sensor and at least one lighting lamp, wherein the control unit is connected with the light collection sensor in a communication mode, the control unit is controllably connected with the lighting lamp, the light collection sensor provides ambient light data, and the control unit controls the working mode of the lighting lamp according to the collected ambient light data.

According to the utility model discloses an embodiment, the luminous working method that is not had the flicker of light.

According to the utility model discloses an embodiment, during light collection sensor gathered ambient light, the light quilt the control unit control and light-emitting pause.

According to the utility model discloses an embodiment, the light by the control unit control and during luminous, light collection sensor pauses to provide the data of gathering ambient light.

According to the utility model discloses an embodiment, the length of time of light collection sensor pause collection environment light is greater than far away the length of time that the light pause is luminous.

According to the utility model discloses an embodiment, the length of time of light pause work is less than or equal to 100 ms.

According to an embodiment of the present invention, the control unit comprises a lamp circuit control block, a feedback control block, a timer, and a determiner, wherein the lamp circuit control block is controllably connected to the illumination lamp, wherein the feedback control block is communicably controllably connected to the light collection sensor, wherein the timer is respectively connected to the lamp circuit control block and the feedback control block, wherein the determiner is respectively connected to the lamp circuit control block, the feedback control block, and the timer.

According to the utility model discloses an embodiment, the timer time the light with light collection sensor's pause on time respectively, wherein according to the timing of timer, lamp circuit control block is regularly exported the definite right of decision ware control of light.

According to the utility model discloses an embodiment, according to the timing of timer, lamp way control block control the opening of light is closed, wherein according to the processing of decision ware, lamp way control block control the working method of light.

According to the utility model discloses an embodiment, the feedback control piece includes a feedback switch end and a feedback receiving terminal, wherein the feedback switch end is controllably connected light collection sensor makes light collection sensor is controlled whether to provide the sensing data, wherein the feedback receiving terminal communicably connect in light collection sensor makes light collection sensor is controlled via the feedback receiving terminal to the decision ware provides the sensing data.

According to the utility model discloses an embodiment, the decision maker includes a comparison end and a record notice end, wherein the comparison end is prestored the processing method, wherein according to the ambient light data that light acquisition sensor gathered, the comparison end obtains needing the control mode of how the light worked, wherein the record notice end is connected with gathering the timer with the comparison end.

According to another aspect of the utility model, the utility model discloses a photosensitive control device is further provided, is suitable for to control a light, include:

a control unit and a light collection sensor, wherein the control unit is communicably connected to the light collection sensor, wherein the control unit is controllably connected to the illumination lamp, wherein the light collection sensor provides ambient light data, wherein the control unit controls the operation of the illumination lamp based on the collected ambient light data.

According to the utility model discloses an embodiment, sensitization controlling means further includes a directional light guide, wherein directional light guide is suitable for fixedly light collection sensor is in a predetermined direction.

According to the utility model discloses an embodiment, light collection sensor is fixed to the light emitting direction of light detects.

According to an embodiment of the present invention, the directional light guide is selected from a group consisting of a lens, a lens set, a light guide tube, and an optical fiber.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the appended claims.

Drawings

Fig. 1 is a schematic flow chart of a sensitization method according to a preferred embodiment of the present invention.

Fig. 2 is a schematic diagram of current output waveforms of the photosensitive control device, the non-stroboscopic photosensitive illumination lamp and the photosensitive method according to the above preferred embodiment of the present invention.

Fig. 3 is a schematic output waveform diagram of the output control terminal of the sensitization control device and the non-stroboscopic sensitization lighting fixture and sensitization method according to the above preferred embodiment of the invention.

Fig. 4 is a brightness adjustment curve diagram of the sensitization control device and the non-stroboscopic sensitization lighting fixture and sensitization method according to the above preferred embodiment of the invention.

Fig. 5 is a schematic diagram of light variation waveforms of the photosensitive control device, the non-stroboscopic photosensitive illumination lamp and the photosensitive method according to the above preferred embodiment of the present invention.

Fig. 6 is a schematic overall structure diagram of the non-stroboscopic lighting fixture according to the above preferred embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a non-stroboscopic lighting fixture according to the above preferred embodiment of the present invention.

Fig. 8 is a block diagram schematically illustrating the structure of the photosensitive control device according to the above preferred embodiment of the present invention.

Fig. 9 is a reminding schematic diagram of the non-stroboscopic lighting device according to the above preferred embodiment of the present invention.

Fig. 10A and 10B are schematic diagrams of variability luminescence recorded in association with outside information for the strobe-less sensitive illumination lamp according to the above preferred embodiment of the present invention.

Fig. 11 is a split schematic view of a non-stroboscopic lighting fixture according to the above preferred embodiment of the present invention.

Fig. 12 is a schematic diagram of the adjustment effect of the non-stroboscopic lighting device according to the above 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 a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purpose of limitation.

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 utility model provides a sensitization method of sensitization controlling means, as shown in figure 1 and figure 2, sensitization method includes following step:

I. judging whether to end an output period, if so, entering a detection period, and if not, waiting for the end of the output period and keeping executing the set light-emitting parameters;

acquiring ambient light information during the detection period, and entering a new output period after the detection period is finished; and

and III, setting a light-emitting parameter according to the ambient light information collected during the detection period.

As shown in FIG. 2, for the convenience of illustration, the execution period of the sensitization method is T, and the duration of the output period is T-T_timThe detection period is T_tim. The duration of the execution period of the sensitization method is far longer than the detection period, i.e. T > T_tim. The duration of the output period being substantially greater than the detection period, i.e. T-T_tim＞＞T_tim。

Specifically, the light emission parameters set in step III are executed in a new output period.

Preferably, step III of the sensitization method is performed when step II is performed. That is, during the detection, the light emission parameters are adjusted, and step III is performed during the detection. In a more preferable mode, step III of the sensitization method is performed after step II, and step III is performed in the output period. That is, in the output period, the light emitting parameter is adjusted, and therefore, the light sensing method of the present invention includes the step I, the step II, and the step III without limiting the order between the step I, the step II, and the step III.

More specifically, in the output period of step I, the photosensitive control device provides a corresponding dc output according to the set lighting parameters to provide an electrical energy output for at least one lighting lamp adopting a flashless lighting mode, wherein the photosensitive method first determines whether the output period is finished, and in the output period, current output is performed according to predetermined lighting parameters. That is, the illumination lamp suspends the adjustment lighting in a state where the strobe-free lighting is continued. The predetermined light-emitting parameter referred to herein may be a preset light-emitting parameter for starting the light-sensing control device, or may be a light-emitting parameter set after the previous adjustment. Secondly, when the output period is finished, entering the detection period and starting to collect the information of the ambient light. During the detection period, a non-luminous mode is adopted, namely the photosensitive control device does not provide current output for the illuminating lamp, and only the external environment light is sensed. That is, during the detection, the illumination lamp is suspended from emitting light. And finally, after the detection period is finished, adjusting the light-emitting parameters according to the acquired information of the ambient light. And in the new output period, the photosensitive control device provides corresponding current output for the illuminating lamp according to the adjusted light-emitting parameters, and cyclically waits for the end of the output period.

It is worth mentioning that the illumination lamp continuously emits light in the output period, thereby ensuring the illumination effect. During the detection period, the ambient light is detected by the photosensitive control device in a non-luminous mode, and the luminous parameters are adjusted according to the ambient light condition, so that the light is emitted according to the adjusted luminous parameters in a new output period. Moreover, during the detection, because the illuminating lamp does not emit light, the light emission of the illuminating lamp cannot be sensed, namely, the detection of the ambient light by the photosensitive control device cannot be interfered by the light emission of the illuminating lamp, and the reasonability of the adjusted light emission parameters is further ensured. For example, the lighting parameters corresponding to the target brightness and/or color temperature are preset, and the lighting parameters are adjusted according to the ambient light detection result in the detection period, so that the ambient light is matched with the lighting of the lighting lamp, and the lighting effect of the lighting is achieved, thereby achieving the target brightness and/or color temperature. Based on the pure detection of the ambient light, the adjustment algorithm becomes direct, which is beneficial to calculating and shortening the time for adjusting the brightness. The detection and adjustment are carried out during the detection, the illumination adjustment is directly carried out on the use environment, and the normal light emitting work cannot be influenced.

Preferably, in the output period, the photosensitive control device outputs corresponding direct current according to the light emitting parameters, so that the illuminating lamp can continuously ensure illumination in a flash-frequency-free light emitting mode, and eye health of light emission is ensured.

Preferably, during the detection period, a corresponding light emitting parameter is generated according to a sensing result of the ambient light, and the output current of the photosensitive control device is adjusted according to the light emitting parameter, so that the detection and the light emitting parameter adjustment are suspended and light is continuously and stably emitted in the output period.

More, before step I, the sensitization method further comprises the steps of:

and (4) determining whether to start adjusting the output current according to the light-emitting parameters, if so, entering the step (II), and if not, keeping the current output corresponding to the original light-emitting parameters.

Specifically, the sensitization method preferentially determines whether or not the light emission needs to be adjusted. For example, the user confirms that the mode of light emission adjustment is turned on, and then starts the execution cycle of the output period and the detection period. For another example, if the user confirms that adjustment is not necessary or that the light emission parameter setting needs to be maintained, the light emission illumination corresponding to the set light emission parameter is maintained.

More, after the step III, the sensitization method further comprises the steps of:

storing the adjusted light-emitting parameter record and generating a time-dependent adjustment record.

In particular, the adjustment record is periodic for the lighting parameters adjusted over time. The adjustment record can be directly used by the illuminating lamp without restarting the sensitization method, and the brightness is adjusted according to the adjustment record. In a possible embodiment, the adjustment record is a record of the lighting parameters corresponding to the lighting of the room in a certain afternoon period, and the light sensing control device directly controls the output current according to the adjustment record. That is, targeted light emission adjustment can be achieved without going through the detection period again.

The detection period T is set to be longer than the detection period T_timThe duration of (a) is short, with a short pause that is not recognizable by the human eye. Preferably, the detection period is less than or equal to 100ms, T_timLess than or equal to 100 ms. More preferably, the detection period is equal to or less than 1 ms.

In particular, since the illumination intensity itself does not need to be considered during the detection, the sensing of the ambient light is more direct, and the calculation and decision processing time is also shorter. The control process of the required light emission intensity can be sufficiently performed during the detection.

It is worth mentioning that the output of the illumination lamp by the light sensing control device can be directly cut off in the process of switching the output period to the detection periodThe light output of the illuminating lamp is stopped instantly, which is beneficial to reducing the detection period T_timIs not recognized by human eyes during the detection period, and the influence of light emission of the illumination lamp is instantaneously eliminated to enable the detection period T_timIs effectively obtained, while for the execution of the adjusted target brightness and/or color temperature, a gradual transition is preferably used, such as at the end of the detection period T_timAnd then starting the output period, wherein the output current of the photosensitive control device is controlled to smoothly transit to the output current determined according to the light-emitting parameters. That is, if the adjustment after the detection period is different from the target brightness and/or color temperature before the detection period, the target brightness and/or color temperature is smoothly adjusted to the newly adjusted target brightness and/or color temperature within a certain delay time. The lighting environment is prevented from being suddenly changed, the experience feeling is improved, and the impact of current on the lighting lamp is reduced so as to prolong the service life of the lighting lamp.

Specifically, in this embodiment of the present invention, after the end of the detection period T _ tim, a new output period is started in which the gradual excess for the adjusted target brightness and/or color temperature is performed in two steps:

(1) the output current of the photosensitive control device is controlled to delay and increase to the output current of the last output period, if the characteristic of an inductor element with a buffering function is utilized, the output current of the photosensitive control device is controlled to smoothly increase to the last output current of the output period in a mode of gradually switching on a switch with the element with the buffering function, so that the influence of current impact on the illuminating lamp is reduced, and the flickering of the illuminating lamp caused by the sudden change of the output current of the two adjacent output periods is avoided.

(2) And controlling the output current of the photosensitive control device to delay and transit to the output current determined according to the current light-emitting parameters of the output period.

In particular, the above is bright for the adjusted target in the output periodThe two-step execution step of the gradual transition of the degree and/or color temperature is carried out at T-T_timThe duration of the output period is not limited, that is, by controlling the light sensing control device, the output current of the light sensing control device can be adjusted to the output current determined according to the current light emitting parameter of the output period at any time point of the output period, which is not limited by the invention.

That is, in the new output period, the gradual transition of the adjusted target brightness and/or color temperature does not involve the adjustment of the lighting parameters, and particularly, in this embodiment of the present invention, in order to simplify the setting of the lighting parameters in step III, the lighting parameters performed in step I are used as a reference, in step III, the reference is adjusted according to the ambient light information collected during the detection period to set the lighting parameters, and when step I is entered again, the lighting parameters set in step III are kept and used as a new reference. Thus, the light-emitting parameters are set in a dynamic compensation mode according to the ambient light information collected during the detection period.

As shown in fig. 2 and 3, a waveform adjusted based on the output current of the illumination lamp by the light sensing control device and a corresponding control waveform are illustrated. By way of example, those skilled in the art will appreciate that some values are merely convenient to visually interpret the sensitization method and are not intended to be a specific limitation on the sensitization method. Illustratively, the default current for the illumination lamp when turned on is 800 mA. Namely, after the device is started, the output current of the photosensitive control device is maintained at 800 mA. After confirming whether or not to start the light emission adjustment, the start of the adjustment is confirmed. After the output period is finished, the detection period T _ tim is started to enter, and the light sensing control device suspends current output so that the illuminating lamp is suspended to emit light. And acquiring data of ambient light during the detection period T _ tim. According to the condition of the ambient light, determining how to adjust the light-emitting state so as to determine the output current of the photosensitive control device and the light-emitting parameters corresponding to the output current. After the detection period T _ tim is ended, the output period is started. In the output period, the output current of the photosensitive control device is determined according to the light-emitting parameters. For example, in fig. 2, since the ambient light collected in the detection period T _ tim is strong, it is determined to adjust the light emitting parameter so that the corresponding output current is 500mA, and in a new output period, firstly, according to the on control signal of the switch with the element having the buffering function illustrated in fig. 3, the output current of the photosensitive control device is controlled to be gradually increased to the output current of 800mA of the previous output period in a manner of gradually turning on the switch, and then the output current of the photosensitive control device is further controlled to be gradually transited from 800mA to the output current of 500mA determined according to the light emitting parameter of the current output period, and is maintained until the end of the output period. When the detection period T _ tim is entered again, the current output is suspended. For example, if it is found out that the external environment to be illuminated is dark again in the collection of the ambient light, and the illumination intensity needs to be increased, it is determined that, in the next output period, the output current of the photosensitive control device is first controlled to be gently increased to the output current of 500mA in the previous output period, then the output current of the photosensitive control device is further controlled to be gently transited from 500mA to the output current determined according to the lighting parameter of the next output period, for example, the output current of 1000mA, and the output current is maintained until the end of the output period, and the photosensitive method is executed by analogy.

As shown in fig. 4 and 5, a waveform diagram of the adjustment recording and a corresponding waveform diagram of the change of the light are illustrated. The profile of the data of the executed lighting parameters is recorded over time. Based on the above example, the recorded data of the luminescence parameters correspond to the respective output currents, without starting the adjustment, as according to the detection period T in the previous method cycles_timThe default light emitting parameter corresponding to the output current of 800mA set in the previous method periods is kept. After the adjustment is started, the output period is ended, and the detection period T is started_timAnd the illuminating lamp is temporarily stopped to emit light. During said detection period T_timTo adoptData of ambient light is collected. According to the condition of the ambient light, determining how to adjust the light-emitting state, and determining the light-emitting parameters corresponding to the corresponding output current. At the end of said detection period T_timThereafter, the output cycle is started. As in the sixth method cycle due to the detection period T_timIf the collected ambient light is strong, the light-emitting parameters are determined to be adjusted to the output current corresponding to 500mA, and the light-emitting parameters and the time are recorded correspondingly. In the new output period, the current output is carried out with the output current of 500mA by adopting the adjusted light-emitting parameter, and the current output is kept until the end of the output period. Re-entering the detection period T_timWhen the current is not output, the output current of 500mA is suspended. For example, when it is found out in the collection of the ambient light again that the ambient environment to be illuminated is dark and the illumination intensity needs to be increased, it is determined to use the light emitting parameter corresponding to the output current of 1000mA in the next output period. After re-entering the output period, using the detection period T_timAnd continuously keeping outputting by using the output current corresponding to the adjusted light-emitting parameter according to the light-emitting parameter determined by the acquired ambient light. That is, in the seventh period, the light emission parameter is performed to correspond to the output current of 1000mA, and accordingly the light emission parameter is recorded with time. The sensitization process generates the adjusted record over time.

Referring to fig. 5, a light variation waveform corresponding to the adjustment recording waveform shown in fig. 4 is illustrated, in which a variation curve of the lamp output varies with a variation curve of the external environment light, so that a mixed light curve of the lamp output and the external environment light is maintained stable due to dynamic compensation of the lamp output. Specifically, in this embodiment of the present invention, the illumination lamp output light value is Lux (illumination lamp output), the external environment light value is Lux (external environment light value), the mixed light value of illumination lamp output and external environment light is Lux (mixed light), wherein Lux (illumination lamp output) is adjusted according to the light emitting parameter corresponding to the change of Lux (external environment light value), in particular, for improving the stability of actual Lux (mixed light), the present invention further introduces a light compensation coefficient k, wherein the mixed light value of illumination lamp output and external environment light satisfies the formula: lux (mixed light) k (Lux (illumination lamp output) + Lux (ambient light value)), wherein by setting Lux (mixed light), the mixed light value Lux (mixed light) of the output of the illumination lamp and the ambient light can be adjusted to suit different illumination requirements, when the external environment light changes to change the Lux (external environment light value), the Lux (illumination lamp output) is adjusted corresponding to the change of the illumination parameter, while the light compensation coefficient k is set corresponding to the difference between the set Lux (mixed light) and the actual Lux (mixed light), so that the actual Lux (mixed light) is maintained stable corresponding to the set Lux (mixed light) to adapt to different lighting requirements, and facilitates improving the consistency of different said photosensitive control means having the same Lux (mixed light) setting.

It should be noted that the setting of the Lux (mixed light) can be realized by means of dial switch, remote control, and remote data setting, which is not limited in the present invention. The setting of the light compensation coefficient k can be dynamically adjusted according to the difference between the set Lux (mixed light) and the light value detected by the photosensitive control device in the output period, wherein it can be understood that the light compensation coefficient k of the same photosensitive control device tends to be fixed according to the inherent error of each electronic component of the photosensitive control device, and the light compensation coefficient k can also be manually adjusted, and is set by dialing switches, remote control, remote data setting and the like, which is not limited by the invention.

It should be noted that, in the preferred embodiment, the output period is at least 10min, and in the output period, the current output is performed by using the light emitting parameter determined according to the detection of the ambient light. Entering the detection period T after the output period is ended_timSaid detection period T_timUp to 100 ms. That is, in the present preferred embodiment, the output period is set to be more than 6000 times as long as the detection period. Therefore, the temperature of the molten metal is controlled,as shown in fig. 4, the variation curve of the recorded data of the lighting parameters is a continuous variation curve of the corresponding output current corresponding to the lighting parameters over time, that is, as shown in fig. 5, the lighting lamp provides continuous lighting in a non-stroboscopic manner, and the overall light formed by the light of the lighting lamp and the ambient light is maintained to be balanced, thereby providing a stable lighting environment.

The adjustment record is adapted to be directly invoked. That is, the light sensing control device can adjust the lighting of the lighting lamp according to the adjustment record without starting the light sensing method again.

It will be understood by those skilled in the art that the output current corresponding to the lighting parameters exemplified in the preferred embodiment is a way to adjust the brightness and/or color temperature. The proportion of the output current to the lighting data is different according to different types of lamps, and the output current and the corresponding lighting parameters corresponding to the required lighting data can be determined according to the types of the lamps.

As shown in fig. 6, the present invention further loads at least one lighting lamp 30 on the photosensitive control device to provide a non-stroboscopic photosensitive lighting fixture, wherein the photosensitive control device comprises a control unit 10 and a light collection sensor 20, wherein the light collection sensor 20 collects ambient light data, the control unit 10 is communicably connected to the light collection sensor 20, the control unit 10 is controllably connected to the lighting lamp 30, and controls the operating mode of the lighting lamp 30 according to the collected ambient light data. In particular, the operation mode of the illumination lamp 30 in this embodiment of the present invention is mainly required on the brightness, and of course, in other embodiments, the color temperature, the color, and other illumination modes of the illumination lamp 30 can be required by setting the control unit 10.

During the light collection operation of the light collection sensor 20, the illumination lamp 30 is controlled by the control unit 10 not to emit light. The data collected by the light collection sensor 20 is irrelevant to the illumination of the illumination lamp 30. The control unit 10 can obtain a pure ambient light condition, and calculate or select a lighting parameter setting required by the lighting lamp 30 to control the operating mode of the lighting lamp 30 according to the lighting parameter.

The illumination of the illumination lamp 30 is flicker-free. The control unit 10 controls the illumination lamp 30 to operate according to the set light emitting parameters and to constantly and stably illuminate. And the light collection sensor 20 is preferably set not to collect ambient light during the lighting operation of the illumination lamp 30. That is, once the illumination lamp 30 is controlled to emit light, the light collection sensor 20 is preferably set to be temporarily stopped.

In particular, it should be understood by those skilled in the art that, in some embodiments of the present invention, during the lighting operation of the lighting lamp 30, the light collecting sensor 20 still collects the ambient light, but the control unit 10 does not control the operation mode of the lighting lamp 30 according to the ambient light data collected by the light collecting sensor 20 during the lighting operation of the lighting lamp 30.

More, the time length of the pause of the light collection sensor 20 is much longer than the time of the pause of the illumination lamp 30. The illumination lamp 30 temporarily stops emitting light for a time period that is not noticeable to the human eye, so that the overall illumination effect is stable. That is, the illumination lamp 30 does not affect the continuous illumination during the pause period of the illumination lamp 30, and the illumination lamp 30 emits light continuously without a flash frequency as observed by human eyes.

During the period when the lighting lamp 30 is not in operation, the light collection sensor 20 can detect external data without self-lighting effect. The control unit 10 is also relatively brief for relatively pure feedback data processing speed, and can fully complete the acquisition and processing during the period of the suspension of the operation of the illumination lamp 30. After the illumination of the illumination lamp 30 is resumed, the illumination lamp is operated in a brightness mode determined by the processing.

Further, as shown in fig. 7 and 8, the control unit 10 includes a lamp control block 11, a feedback control block 12, a timer 13, and a determiner 14. The light circuit control block 11 is controllably connected to the illumination lamp 30. The feedback control block 12 is communicatively and controllably connected to the light collection sensor 20. The timer 13 is connected to the lamp circuit control block 11 and the feedback control block 12, respectively. The determiner 14 is connected to the lamp control block 11, the feedback control block 12, and the timer 13, respectively.

The feedback control block 12 obtains the collected data from the light collection sensor 20 and sends the data to the decision device 14 for processing. The timer 13 respectively counts the pause time of the illumination lamp 30 and the light collection sensor 20. In accordance with the timing of the timer 13, the lamp control block 11 outputs the output current to the illumination lamp 30 determined by the determiner 14 at a timing.

Specifically, the light circuit control block 11 controls whether the illumination lamp 30 is operated or not, based on the timing of the timer 13. The light circuit control block 11 controls the output current to the illumination lamp 30 according to the processing of the determiner 14.

Specifically, the feedback control block 12 controls whether the light collection sensor 20 operates or not according to the timing of the timer 13. The determiner 14 controls the output current of the lamp circuit control block 11 to the illumination lamp 30 according to the data received by the feedback control block 12 from the light collection sensor 20.

More specifically, according to the timing of the timer 13, the light circuit control block 11 controls the lighting lamp 30 to pause and the feedback control block 12 controls the light collection sensor 20 to operate. The light collection sensor 20 begins collecting data of ambient light and the feedback control block 12 receives data from the light collection sensor 20. According to the detection result of the feedback control block 12, the determiner 14 calculates or selects the lighting parameter setting required by the illumination lamp 30, and controls the output current of the illumination lamp 30 from the lamp circuit control block 11 according to the lighting parameter, thereby realizing the control of the operation mode of the illumination lamp 30. For example, the operation modes such as the brightness, color temperature and color of the illumination lamp 30 are controlled. According to the timing of the timer 13, the lamp circuit control block 11 controls the illumination lamp 30 to start operating, and performs the flash-frequency-free illumination operation according to the illumination parameters calculated or selected by the determiner 14. The timer 13 restarts counting time.

The lamp circuit control block 11 comprises an output control terminal 111 and a pause control terminal 112, wherein the output control terminal 111 is controllably connected to the illumination lamp 30, so that the current output to the illumination lamp 30 is controlled by the output control terminal 111, and wherein the pause control terminal 112 is controllably connected to the illumination lamp 30, so that whether the illumination lamp 30 operates or not is controlled by the pause control terminal 112. That is, the pause control 112 controls whether the illumination lamp 30 is operated or not according to the timing of the timer 13, and the output control terminal 111 controls the operation mode of the illumination lamp 30 according to the light emission parameter calculated or selected by the determiner 14.

Further, in this embodiment of the present invention, the pause control terminal 112 is configured as a switching element capable of being controlled to turn on gradually, such as a switch with an element having a buffering function, so that in a new output period, the pause control terminal 112 can control the output of the output control terminal 111 to the illumination lamp 30 in a gradually turning on manner according to the control signal shown in fig. 3, so as to control the output current of the photosensitive control device to gradually increase to the output current of the previous output period in the new output period, thereby achieving a gradual transition of the adjusted target brightness and/or color temperature in the new output period.

The feedback control block 12 comprises a feedback switch terminal 121 and a feedback receiving terminal 122, wherein the feedback switch terminal 122 is controllably connected to the light collection sensor 20, so that the light collection sensor 20 is controlled to provide sensing data, and wherein the feedback receiving terminal 122 is communicably connected to the light collection sensor 20, so that the light collection sensor 20 is controlled to transmit the detected ambient light data to the determiner 14 via the feedback receiving terminal 122. It should be noted that the suspension of the operation of the light collection sensor 20 refers to suspension of providing feedback data. In a possible embodiment, the light collection sensor 20 can be controlled by the feedback switch terminal 121 to directly keep working, and the feedback receiving terminal 122 provides feedback data periodically according to the timer 13. In another possible embodiment, the light collection sensor 20 may be controlled by the feedback switch terminal 121 to operate periodically according to the timer 13, and the feedback receiving terminal 122 provides feedback data to the determiner 14. Preferably, the feedback switch end 121 controls the light collection sensor 20 to be switched on and off periodically, so as to save power consumption.

The timer 13 includes a detection period timing terminal 131 and an output period timing terminal 132, wherein the detection period timing terminal 131 and the output period timing terminal 132 are connected end to end, the detection period timing terminal 131 clocks the detection period, and the output period timing terminal 132 clocks the output period. The timing end 131 times to the node during the detection period, the illumination lamp is controlled by the pause control end 112 to pause, and the light collection sensor 20 provides the collected ambient light data to the feedback receiving end 122. That is, the strobe-free photosensitive illumination lamp enters the detection period. The output period timing terminal 132 counts the time to the node, and the illumination lamp is controlled by the pause control terminal 112 to start to operate and operates according to the output current of the output control terminal 111. The light collection sensor 20 is suspended from providing collected ambient light data to the feedback receiver 122. That is, the strobe-free sensitization lighting fixture enters the output period. The end of the timing of the detection period timing end 131 is the start of the timing of the output period timing end 132, and the end of the timing of the output period timing end 132 is the start of the timing of the detection period timing end 131. That is, when the detection period ends, the output period is entered, and when the output period ends, the detection period is entered.

The determiner 14 includes a comparing terminal 141, wherein the comparing terminal 141 pre-stores comparison data of lighting parameters and corresponding ambient light data, and obtains lighting parameters of how the lighting lamp 30 needs to operate according to the ambient light data collected by the light collecting sensor 20. Preferably, the comparing terminal 141 obtains the current of the illuminating lamp 30 according to the feedback ambient light data. The comparison terminal 141 processes the feedback data obtained from the feedback receiving terminal 122 to control the output current of the output control terminal 111 to the illumination lamp 30. For example, the received ambient light data is obtained from the feedback receiving terminal 122, and compared with the pre-stored comparison data to obtain the corresponding lighting parameter required by the lighting lamp 30, and the output control terminal 111 is controlled to output the corresponding output current according to the lighting parameter, so as to obtain the lighting mode of the lighting lamp 30 corresponding to the lighting parameter. It will be understood by those skilled in the art that the pre-storing manner of the comparing terminal 141 can be changed by programming.

The determining unit 14 further includes a record notifying terminal 142, wherein the record notifying terminal 142 collectively connects the timer 13 and the comparing terminal 141. The record notification end 142 stores the lighting parameter obtained by the comparison end 141 according to the ambient light data collected by the light collection sensor 20 in association with the time period of the timer 13, so as to generate the adjustment record. One waveform of the adjustment recording is shown in fig. 4. Of course, in other embodiments, the adjustment record is stored in the form of table or array data. The adjustment record is adapted to be directly invoked. That is, the non-stroboscopic lighting fixture can control the output control terminal 111 and the pause control terminal 112 of the lighting control block 11 to adjust the light emission of the illumination lamp 20 according to the adjustment record without turning on the timer 13 and the comparison terminal 141 again.

More specifically, as shown in fig. 9, the record notification terminal 142 performs a reminding notification on the recorded problems in the adjustment record according to a pre-stored threshold.

In an exemplary embodiment, the default light emitting parameters set in the first few cycles are set to have an output current of 800mA without starting the adjustment. After the adjustment is started, the output period timed by the timer 13 is ended and startedWhen the detection period starts, the illumination lamp 30 is controlled by the pause control terminal 112 to pause the illumination. During the detection period, the light collection sensor 20 is turned on by the feedback switch terminal 121 to collect the data of the ambient light. According to the ambient light condition received by the feedback receiving end 122, the comparing end 141 determines the light emitting parameter how to adjust the light emitting state, and determines the output current of the output control end 111 according to the light emitting parameter. After the timer 13 finishes counting the detection period, the counting of the output period is started. In the preferred embodiment, the output period is at least 10min, and in the output period, the output control terminal 111 outputs according to the determined output current. And entering the detection period after the output period is ended, wherein the detection period is at most 100 ms. That is, in the present preferred embodiment, the output period is set to be more than 6000 times as long as the detection period. Due to the detection period T_timIf the collected ambient light is dark, the comparing terminal 141 determines to adjust the output current of the output control terminal 111 to the output current Max corresponding to the maximum light emitting brightness of the illumination lamp 30. As shown in fig. 9, in the fourth period, the output current of the output control terminal 111 is performed as the output current Max corresponding to the maximum light emission luminance, and accordingly the output current is recorded with time. In the new output period, the output control terminal 111 current-outputs the illumination lamp 30 at an output current Max so that the illumination lamp 30 is performed to the maximum light emission luminance, and holds until the end of the output period. When the detection period is entered again, the pause control terminal 112 pauses the supply of the output current holding the output current Max. When the light collection sensor 20 collects ambient light again, it is found that the external environment requiring illumination is dark and illumination intensity needs to be increased, the comparison terminal 141 determines to continue to keep the output control terminal 111 to output current Max for current output in the next output period according to collected ambient light data. After entering the output period again, the output control terminal 111 performs current output using the output current Max determined during the detection period, and continuously outputs the output current MaxAnd keeping the current output by using the adjusted output current. That is, in the fifth period, the output control terminal 111 is executed to perform current output to the illumination lamp 30 at the output current Max, and accordingly the output current and time are recorded by the recording notification terminal 142. The voltages of the third to eighth periods in the adjustment record are the maximum light emitting voltage Max with the change of time. The recording notification terminal 142 gives a prompt, and an illuminating lamp is required to be added to the external environment. For example, a reminder to increase the number of the illumination lamps 30.

More specifically, as shown in fig. 10A, the record notifying terminal 142 stores the recorded adjustment records in a classified manner according to the weather information of the outside world. And under the condition of being associated with the external weather information, storing the adjustment record along with the change of the weather information. It is worth mentioning that the adjustment record is mainly stored with the adjusted part and the unadjusted part is discarded. In a sunny weather, the output period timed by the timer 13 is ended, the detection period is started, and the illumination lamp 30 is controlled by the pause control terminal 112 to pause illumination. During the detection period, the light collection sensor 20 is turned on by the feedback switch terminal 121 to collect the data of the ambient light. According to the condition of the ambient light received by the feedback receiving end 122, the comparing end 141 determines the adjustment of the light emitting state according to the light emitting parameter corresponding to the received ambient light, specifically, determines the output current of the output control end 111 by adjusting the output current according to the light emitting parameter. After the timer 13 finishes counting the detection period, the counting of the output period is started. In the preferred embodiment, the output period is at least 5min, and in the output period, the output current determined from the detection is used. And entering the detection period after the output period is ended, wherein the detection period is at most 100 ms. That is, in the present preferred embodiment, the output period is set to be greater than 3000 times the detection period or more. Since the ambient light collected during the detection period is strong, the comparison terminal 141 determines to adjust the output current outputted from the output control terminal 111 to the illumination lamp 30 to 300 mA. With the time lag, in the sixth period, the output current of the output control terminal 111 is performed to 300mA, and accordingly, the output current and the time are recorded. In the new output period, the illumination lamp 30 emits light with the adjusted output current of 300mA, and keeps until the end of the output period. When the detection period is entered again, the suspension control terminal 112 suspends the supply of the output current of 300mA for holding the illumination lamp 30. When the light collection sensor 20 finds that the external environment needing illumination is brighter and the illumination intensity needs to be reduced in the collection of the ambient light again, the comparison terminal 141 determines, by comparison, that the output control terminal 111 uses 500mA of output current in the next output cycle. After entering the output period again, the output control terminal 111 continuously keeps using the adjusted output current for current output by using the output current determined according to the ambient light data collected during the detection period. That is, in the seventh period, the output current of the output control terminal 111 to the illumination lamp 30 is performed to be 500mA, and accordingly the output current and time are recorded by the recording notification terminal 142. Over time, the adjustment records record output current adjustment values and are sorted in relation to weather information. In the case of the non-stroboscopic lighting fixture which works by calling a plurality of adjustment records, the adjustment record closest to the user is selected according to the use weather, so that the non-stroboscopic lighting fixture is more friendly to light.

As shown in fig. 10B, the record notification terminal 142 stores the recorded adjustment records in a finely classified manner according to the change of the weather information of the outside. And when the weather information related to the outside changes, the time and the weather are related to change, and the adjustment records are generated and stored in a classified manner. In a case of a weather of changing from sunny to rainy, the output period timed by the timer 13 ends, and starts to enter the detection period, and the illumination lamp 30 is controlled by the pause control terminal 112 to pause to emit light. During the detection period, the light collection sensor 20 is turned on by the feedback switch terminal 121 to collect the data of the ambient light. According to the ambient light condition received by the feedback receiving end 122, the comparing end 141 compares and determines the light emitting parameter for adjusting the light emitting state, and determines the output current of the output control end 111 according to the light emitting parameter. After the timer 13 finishes counting the detection period, the counting of the output period is started. In the preferred embodiment, the output period is at least 5min, and in the output period, the output current determined from the detection is used. And entering the detection period after the output period is ended, wherein the detection period is at most 100 ms. That is, in the present preferred embodiment, the output period is set to be greater than 3000 times the detection period or more. Since the ambient light collected during the detection period is strong, the comparison terminal 141 determines to adjust the output current of the output control terminal 111 to the illumination lamp 30 to be 500 mA. With the time delay, in the sixth period, the output current of the output control terminal 111 is performed to be 500mA, and accordingly, the output current and the time and weather are recorded. In the new output period, the illumination lamp 30 emits light with the adjusted output current of 500mA, and keeps until the end of the output period. When the detection period is entered again, the pause control terminal 112 pauses the output voltage supply of 500mA to the illumination lamp 30. When the light collection sensor 20 finds that the external environment to be illuminated is dark and the illumination intensity needs to be increased in the collection of the ambient light again, the comparison terminal 141 determines that the output control terminal 111 uses 1000mA of output current in the next output cycle. After entering the output period again, the output control terminal 111 uses the output current determined according to the collected ambient light data during the detection period, and keeps continuously using the adjusted output current for output illumination. That is, in the seventh period, the output current to the illumination lamp 30 is performed to 1000mA, and accordingly, the output current and the information of the time and the weather change are recorded by the recording notification terminal 142. The adjustment records record output current adjustment values and classify in relation to weather change information as a function of time. Generally, the strobeless illuminated lighting fixture is fixedly installed, and the external environment thereof is relatively stable. By means of intelligent learning, the adjustment records can be used in sections, and even the lighting can be adjusted according to the weather and the time without feedback detection again.

The strobeless illuminated lighting fixture further includes a lamp housing 101 and a lamp body 102, as shown in fig. 11, wherein the control unit 10, the illuminating lamp 30 and the light collection sensor 20 are accommodated between the lamp housing 101 and the lamp body 102. The light collection sensor 20 is close to the illuminating lamp 30 and is arranged, so that under the condition that the illuminating lamp 30 is in pause operation, the light collection sensor 20 obtains the ambient light data of the position of the illuminating lamp 30, and the influence of light emitted by the non-stroboscopic photosensitive illuminating lamp on the collected ambient light data is reduced. The control unit 10 is more direct to control the lighting of the illumination lamp 30 according to the data close to the ambient light data of the illumination lamp 30, and the result of the adjustment of the illumination lamp 30 is more suitable for the requirement.

In this preferred embodiment, the plurality of illuminating lamps 30 are uniformly arranged in the lamp housing 101, wherein the light collecting sensor 20 is surrounded by the plurality of illuminating lamps 30, and preferably, the light collecting sensor 20 is disposed at a central position relative to the plurality of illuminating lamps 30.

It can be understood that the present invention provides a photosensitive control device, which controls at least one of the illuminating lamps 30 to achieve different illumination effects. That is, the light sensing control device may be directly connected to the illumination lamp 30 to perform a control execution operation of switching or adjusting the on operation. The photosensitive control device comprises the control unit 10 and the light collection sensor 20. Preferably, the sensitization control device operates by adopting the sensitization method.

It can be understood that the structure and connection relationship of the control unit 10 and the light collection sensor 20 of the photosensitive control device are similar to those of the non-stroboscopic photosensitive illuminating lamp, and are not described herein again.

In particular, referring to fig. 12 of the drawings accompanying the present application, the photosensitive control apparatus further includes a directional light guide 200. Directional light guide 200 is suitable for certain direction conduction light, in order to change light acquisition sensor 20 is to the collection direction of ambient light, makes light acquisition sensor 20 can carry out ambient light data acquisition to predetermined direction, and then can reduce or avoid right light acquisition sensor 20 shelters from and more accurately acquires correspondingly the ambient light data of the luminous region that light 30 corresponds, and reduce or avoid because of the difference light that no stroboscopic sensitization light utensil sent forms to the influence of the ambient light data of gathering not the mutual interference between the stroboscopic sensitization light utensil. If the orientation of the directional light guide 200 is set to protrude from the lampshade 101 and correspond to the light emitting direction of the corresponding illuminating lamp 30, on one hand, the shielding of the lampshade 101 on the ambient light can be avoided so that the light collection sensor 20 can more accurately acquire the ambient light data of the light emitting area corresponding to the corresponding illuminating lamp 30, and on the other hand, the influence of the light emitted by the illuminating lamp 30 of the other non-stroboscopic lighting fixture on the ambient light data of the ambient area collected by the light collection sensor 20 can be reduced or avoided.

Further, as shown in fig. 12, the non-strobe photosensitive illuminating lamps are arranged in a one-to-one correspondence with the photosensitive control devices. That is, when there are a plurality of the non-stroboscopic photosensitive illumination lamps in the same spatial range, the directions of the directional light guides 200 of each photosensitive control device can be prevented from intersecting with each other. That is, the light collection sensor 20 detects ambient light in an ambient space where the stroboscopic-free photosensitive illumination lamp is located. The light collection sensor 20 of each photosensitive control device detects a certain environmental space, and reduces the influence of the adjacent non-stroboscopic light-sensitive lighting fixtures or other unstable light sources on the control, so that in the same spatial range, each non-stroboscopic light-sensitive lighting fixture can emit light according to the environmental light of the environment where the non-stroboscopic light-sensitive lighting fixture is located, so that the overall light of each lighting interval corresponding to different non-stroboscopic light-sensitive lighting fixtures in the spatial range is maintained to be balanced, for example, in an office in the same spatial range, the non-stroboscopic light-sensitive lighting fixture close to a window emits light with a lower output current due to the strong environmental light in the corresponding lighting interval, and the non-stroboscopic light-sensitive lighting fixture far away from the window emits light with a relatively increased output current, so as to maintain the balance of the overall light in the office and provide a stable lighting environment, and energy is saved.

Preferably, the directional light guide 200 may be implemented as one or more of a combination of a lens, a lens set, a light guide tube, an optical fiber, a reflector, etc., wherein it is understood that the lens is preferably a condensing lens of a convex lens or a fresnel lens type, and the lens set may be a lens set having condensing characteristics formed by different combinations of the lenses, which is not limited by the present invention.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The objects of the present invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (15)

1. There is not stroboscopic sensitive lighting lamps and lanterns, its characterized in that includes:

the lighting system comprises a control unit, a light collection sensor and at least one lighting lamp, wherein the control unit is connected with the light collection sensor in a communication mode, the control unit is controllably connected with the lighting lamp, the light collection sensor provides ambient light data, and the control unit controls the working mode of the lighting lamp according to the collected ambient light data.

2. The non-stroboscopic light-sensing illumination lamp of claim 1, wherein the illumination of the illumination lamp is a non-stroboscopic mode of operation.

3. The non-stroboscopic light-sensing illumination lamp of claim 1, wherein the illumination lamp is controlled by the control unit to pause illumination during the period when the light collection sensor collects ambient light.

4. The non-stroboscopic light-sensing luminaire of claim 3, wherein during the period that the illumination lamp is controlled by the control unit to emit light, the light collection sensor suspends providing data for collecting ambient light.

5. The non-stroboscopic light-sensing luminaire of claim 3, wherein the duration of the light collection sensor suspending collecting ambient light is much longer than the duration of the illumination light of the illumination lamp suspending emitting light.

6. The non-stroboscopic illuminated lighting fixture of claim 5, wherein the illumination lamp is paused for less than or equal to 100 ms.

7. The non-stroboscopic light-sensing illumination lamp of claim 3, wherein the control unit comprises a lamp circuit control block, a feedback control block, a timer, and a determiner, wherein the lamp circuit control block is controllably connected to the illumination lamp, wherein the feedback control block is communicatively controllably connected to the light collection sensor, wherein the timer is respectively connected to the lamp circuit control block and the feedback control block, wherein the determiner is respectively connected to the lamp circuit control block, the feedback control block, and the timer.

8. The non-stroboscopic light-sensing illumination lamp of claim 7, wherein the timer times the operation suspension time of the illumination lamp and the light collection sensor respectively, wherein the lamp circuit control block periodically outputs the control of the illumination lamp determined by the determiner according to the timing of the timer.

9. The non-stroboscopic light-sensing illumination lamp of claim 7, wherein the light circuit control block controls the illumination lamp to be turned on or off according to the timing of the timer, wherein the light circuit control block controls the operation mode of the illumination lamp according to the processing of the decision device.

10. The non-stroboscopic light-sensing illumination lamp of claim 8, wherein the feedback control block comprises a feedback switch terminal and a feedback receiving terminal, wherein the feedback switch terminal is controllably connected to the light collection sensor such that the light collection sensor is controlled to provide sensing data, wherein the feedback receiving terminal is communicatively connected to the light collection sensor such that the light collection sensor is controlled to provide sensing data to the determiner via the feedback receiving terminal.

11. The non-stroboscopic light-sensing illumination device of claim 8, wherein the determining device comprises a comparing terminal and a recording notification terminal, wherein the comparing terminal is pre-stored, wherein the comparing terminal obtains a control mode of how the illumination lamp needs to operate according to the external light data collected by the light collection sensor, and wherein the recording notification terminal connects the timer and the comparing terminal together.

12. The non-stroboscopic light-sensing illumination lamp of claim 8, wherein the light circuit control block comprises an output control terminal and a pause control terminal, wherein the pause control terminal is disposed between the output control terminal and the illumination lamp to be switched on and off to control the output control terminal, and wherein the output control terminal controls the current output to the illumination lamp according to the ambient light data collected by the light collection sensor.

13. The strobeless illuminated lighting fixture of claim 12, further comprising a directional light guide, wherein the directional light guide is adapted to fix the light collection sensor in a predetermined orientation.

14. The non-stroboscopic light-sensing luminaire of claim 12, wherein the light collection sensor is fixed to detect the direction of illumination of the illumination lamp.

15. The non-stroboscopic illuminated lighting fixture of claim 13, wherein the directional light guide is selected from the group consisting of a lens, a lens set, a light guide tube, and an optical fiber.

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