1. Field of the Invention
The present invention relates to a light emitting diode (LED) control method, and particularly to a control method of color temperature and luminance for an LED device and a control system thereof.
2. Description of the Related Art
An LED device can emit lights of a plurality of different colors and illumination modes. Consumers can buy the LED device for their preference. The colors or illumination modes of a commercially available LED device may be adjusted. However, between the functions of colors and illumination modes, only one function can be adjusted in one LED device.
On the other hand, when the LED device has a function for adjusting the colors or the illumination modes, a controller must be mounted in the LED device. The controller can adjust the colors or the illumination modes of the LED device. A circuit of the controller is complex, and therefore the LED device with the controller becomes more expansive than the LED device without the controller. The consumers may not want to buy the LED device with the controller because of the higher prices of the LED device.
An objective of the present invention is to provide a control method of color temperature and luminance for an LED device and a control system thereof. The control method and the control system can adjust the color temperature and the luminance of the LED device by using a relative simple circuit configuration.
To achieve the foregoing objective, the present invention provides the control method of color temperature and luminance for the LED device comprising the following steps:
In the foregoing steps, the color temperature and the luminance can be exchanged.
If the warm-start motion is executed during the preset time period after the cold-start motion is executed, the LED device will enter a color temperature adjusting mode. In the color temperature adjusting mode, the user can circularly adjust the color temperature of the LED device, while the warm-start motion is executed repeatedly during the preset time period. For example, the color temperature can be adjusted from the cool white to the warm white step by step by repeatedly executing the warm-start motion during the preset time period.
If the warm-start motion is executed after the preset time period, the LED device enters a luminance adjusting mode. In the luminance adjusting mode, the user can circularly adjust the luminance of the LED device, while the warm-start motion is executed repeatedly. For example, the luminance can be adjusted from high brightness to low brightness step by step by repeatedly executing the warm-start motion.
As a whole, the user can adjust the color temperature and the luminance of the LED device by turning off and on the LED device. The user can easily adjust the color temperature and the luminance of the LED device, and a circuit of a controller of the LED device is not complex.
To achieve the foregoing objective, the present invention further provides a control system of color temperature and luminance for the LED device, the control system comprising:
Other objectives, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
With reference to
With reference to
The rectification circuit 12 rectifies an AC of the AC power source to a full wave DC, and outputting the full wave DC. If the AC power source is provided by the mains electricity, a waveform of an output of the rectification circuit 12 will be a waveform of continuous positive half waves, which is called the full wave DC. When the switch 1 is turned on, the waveform of the output of the rectification circuit 12 is shown in a solid line of a waveform (B) in
The optical coupler 13 comprises an input terminal and an output terminal. The input terminal is electronically connected with an output of the rectification circuit 12 for detecting the full wave DC. The output terminal outputs continuous square waves according to the detected full wave DC. When the switch 1 is turned on, a waveform of the output terminal is shown in a solid line of a waveform (C) in
The transforming circuit 14 is electronically connected with the output of the rectification circuit 12 for receiving the full wave DC and transforms the full wave DC to a stable DC voltage, for example, 24V. A waveform of the stable DC voltage is shown in a waveform (D) in
The voltage stabilizer 15 is electronically connected with an output of the transforming circuit 14 for receiving the stable DC voltage and transforms the stable DC voltage to a working DC voltage, for example, 3.3V. A waveform of the working DC voltage is shown in a waveform (E) in
The microprocessor 16 is electronically connected with an output of the voltage stabilizer 15 for receiving the working DC voltage, and also with the output terminal of the optical coupler 13 for receiving the continuous square waves. When the switch 1 is turned off, electrical energy of the AC power source is cut off, and the optical coupler 13 stops outputting the continuous square waves. The microprocessor 16 can determine that the switch 1 is turned on or off according to whether the continuous square waves exist or not. The microprocessor 16 can change the color temperature and luminance. The microprocessor 16 has a pre-stored determining program. The microprocessor 16 can output a color temperature adjusting signal or a luminance adjusting signal according to a switching motion and the determining program for adjusting the color temperature and the luminance. The switching motion is turning on or off the switch 1. The color temperature adjusting signal is a plurality of adjusting values in a sequence. For example, the sequence of the color temperature adjusting signal may be 5500K→4000K→3300K→2700K.
The luminance adjusting signal is another plurality of adjusting values in a sequence. For example, the sequence of the luminance adjusting signal may be 100%→50%→25%→10%→1%.
The control system 10 can adjust the color temperature and luminance of an LED lighting device 20. In the embodiment, the LED lighting device 20 may be a panel light, a fluorescent lamp, a projector lamp, a light bar, or a wash wall lamp. The LED lighting device 20 comprises multiple groups of LEDs. Each group of the LEDs has different color temperatures. For example, a color temperature of a first group 21 of the LEDs is 5500K, and a color temperature of a second group 22 of the LEDs is 2700K. A plurality of mixed color temperatures can be obtained by adjusting a mixing proportion of the first group of the LEDs and the second group of the LEDs. The following table is an example.
The first group 21 of the LEDs and the second group 22 of the LEDs are electronically connected with the output of the transforming circuit 14 for receiving the stable DC voltage. A first current control circuit 211 and a second current control circuit 221 are each respectively and electronically connected with the first group 21 of the LEDs and the second group 22 of the LEDs. An output of the microprocessor 16 outputs the color temperature adjusting signal or the luminance adjusting signal for controlling the first current control circuit 211 and the second current control circuit 221. The first current control circuit 211 can control a current of the first group 21 of the LEDs and the second current control circuit 221 can control a current of the second group 22 of the LEDs for adjusting the color temperature or the luminance of the LED lighting device 20.
In the embodiment, a user can adjust the color temperature or the luminance of the LED lighting device 20 by switching the switch 1 repeatedly. The microprocessor 16 determines whether the user adjusts the color temperature or the luminance of the LED lighting device 20 according to a warm-start motion, a cold-start motion, and a preset time period, for example, a time of correlated color temperature (Tcct). The Tcct is a time for distinguishing a color temperature adjusting mode from a luminance adjusting mode. For example, the time of correlated color temperature is 5 seconds, and the Tcct=5.
With reference to
With reference to the waveform (D) in
When the switch 1 is turned off at the time t1, the optical coupler 13 stops outputting the continuous square waves, and the capacitor 141 of the transforming circuit 14 starts to release the electrical energy. The microprocessor 16 detects whether the AC power source is cut off according to the optical coupler 13. When the AC power is cut off at the time t1, the voltage stabilizer 15 can still output the working DC voltage (For example, 3.3V) according to the electrical energy released by the capacitor 141. When the switch 1 is still off at a time t2, the capacitor 141 is running out of its electricity energy. An output voltage of the transforming circuit 14 cannot be provided to the voltage stabilizer 15 for outputting the working DC voltage. For example, when the output voltage of the transforming circuit 14 is lower than 5V, the voltage stabilizer 15 stops working, and the microprocessor 16 stops working. In another situation, when the switch 1 is turned off at the time t1 and turned on before the time t2, the microprocessor 16 remains working. Therefore, if the switch 1 is turned off at the time t1 and then turned on before the time t2, the activation of the switch 1 is regarded as the warm-start motion. A time period between the time t1 and time t2 is the time period Tws. A duration of the time period Tws is decided by capacitance of the capacitor 141.
When the switch 1 is still not turned on during the Tcs, the capacitor 141 is running out of the electricity energy, and the voltage stabilizer 15 and the microprocessor 16 stop working. When the switch 1 is turned off and then turned on after the Tcs, the microprocessor 16 is reset and restarted. Therefore, if the switch 1 is turned off and then turned on after the Tcs, the activation of the switch 1 is regarded as the cold-start motion.
Furthermore, in the other embodiment, when the warm-start motion is executed without determining whether the warm-start motion is executed during the Tcct, the microprocessor 16 can output an adjusting signal for simultaneously adjusting the color temperature and the luminance of the LED device. The adjusting signal is a plurality of sets of adjusting values changed sequentially. The adjustment of the color temperature and the luminance are executed circularly according to a sequence. For example, the sequence has eight sets of the adjusting values, and the color temperature and the luminance are adjusted according to the sets of the adjusting values form the first set to the eighth set. If the last set, i.e. the eighth set, is currently used, switching to a next set following the eighth set will return to the first set. The color temperature and the luminance are repeatedly adjusted according to the sets of the adjusting values from the first set to the eighth set.
The following table is the example of the eight sets of the adjusting values in the sequence.
The example described above may produce a light variation curve of sunlight from noon to dusk. The first set of the adjusting values corresponds to 5500K (cool white) of the color temperature and 100% of the luminance, and the first set simulates the sunlight of noon. Then the fourth set of the adjusting values corresponds to 4000K (natural white) of the color temperature and 40% of the luminance for simulating the sunlight of afternoon. The eighth set of the adjusting values corresponds to 2700K (warm white) of the color temperature and 1% of the luminance for simulating the sunlight of dusk.
The light variation curve of sunlight from noon to dusk can produce comfortable luminous environments.
With reference to
The luminance is also adjusted circularly in a sequence, for example, the sequence of the luminance may be 100%→50%→25%→10%→1%.
In another embodiment, the color temperature and the luminance can be exchanged. In more detail, the luminance of the LED device is adjusted (S403) when the warm-start motion is executed during the preset time period, Tcct, and when the warm-start motion is executed again during the preset time period, Tcct, the luminance of the LED device is also adjusted again. The luminance is adjusted circularly in a sequence, for example, the sequence of the luminance may be 100%→50%→25%→10%→1%. The color temperature of the LED device is adjusted (S404) when the warm-start motion is not executed in the preset time period, Tcct, and when the warm-start motion is detected again (S405), the color temperature of the LED device is also adjusted again (S404). The color temperature is adjusted circularly in a sequence, for example, the sequence of the color temperature may be 5500K→4000K→3300K→2700K.
In the other embodiment, the control method can be executed by the following steps:
For example, the sequence has eight sets of the color temperature and the luminance, and the color temperature and the luminance are adjusted form the first set to the eighth set. Then, a next set after the eighth set will return to the first set, and the color temperature and the luminance are repeatedly adjusted from the first set to the eighth set.
The following table is the example of sets of the color temperature and the luminance in the sequence.
With reference to
The present invention can adjust the color temperature and the luminance of the LED device by turning off and on the switch 1. The circuit of the control system 10 is not complex, and does not require a complex wiring. The present invention lowers cost in manufacturing, simplifies a manufacturing process, and can adjust both the color temperature and the luminance of the LED device.
Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only. Changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.