Patent Application
20220316665
The present disclosure relates to a light-emitting diode light string control system and a signal identification method thereof, and more particularly to a light-emitting diode light string control system with carrier identification function and a signal identification method thereof.
The statements in this section merely provide background information related to the present disclosure and do not necessarily constitute prior art.
As the applications of light-emitting diodes (LEDs) are becoming more and more popular, and their manufacturing costs are getting lower and lower, the applications of LEDs in lighting or display are becoming more and more widespread. Therefore, there are more and more manners to operate and control lighting behavior of LEDs. In the applications of the LED light string, since it is necessary to set lighting behavior of each LED, the LED light string can produce a visual effect. Accordingly, a controller should be used to control each LED, and each controller also has the function of identifying signals so as to be able to determine whether the signals are specific lighting commands.
Since most of the carrier signals, which are signals carried on a DC voltage, received by the existing LED light strings are high-power and high-frequency switching signals, it is easy to affect the stability of signal identification due to the interference of high-frequency noise of the switching signal. At this condition, it is necessary to use a relatively high-precision identification circuit or circuit components that are more resistant to noise interference to increase the stability of signal identification. However, such high-precision identification circuits or circuit components are usually expensive and their operation manners are also complicated.
Therefore, an LED light string control system with carrier identification function and a signal identification method thereof are provided to accurately identify the signals on the DC voltage and correctly perform the lighting behavior of the LED light string.
In order to solve the above-mentioned problems, an LED light string control system with carrier identification function is provided. The LED light string control system with carrier identification function includes a control module, a power capacitor, and an LED light string. The control module converts a DC voltage to carry signals on the DC voltage through a power switch according to a lighting command. The power capacitor is coupled to an output end of the control module, and performs a capacitive charge-discharge operation to the signals on the DC voltage to generate capacitive charge-discharge signals. The LED light string includes at least one LED module and is coupled to the power capacitor. The at least one LED module identifies that a charge-discharge characteristic is to a first logic, a second logic, or a latch indication, and generates a drive command corresponding to the signals on the DC voltage according to one of the first logic, the second logic, and the latch identification to control lighting behavior of the LED light string.
In order to solve the above-mentioned problems, a signal identification method of an LED light string control system is provided. The signal identification method includes steps of: converting a DC voltage to carry signals on the DC voltage according to a lighting command, performing a capacitive charge-discharge operation to the signals on the DC voltage to generate capacitive charge-discharge signals, identifying a charge-discharge characteristic of the capacitive charge-discharge signals being a first logic, a second logic, or a latch indication, and generating a drive command corresponding to the signals on the DC voltage according to the first logic, the second logic, and the latch indication to control lighting behavior of an LED light string.
The main purpose and effect of the present disclosure are that the power capacitor performs the capacitive charge-discharge operation to the signals on the DC voltage to generate the capacitive charge-discharge signals and the LED module identifies the charge-discharge characteristic of the capacitive charge-discharge signals so that the circuit components are simple, the operation is easy, and the signals on the DC voltage can be accurately identified and the lighting behavior can be correctly performed.
It is to be understood that both the foregoing general description and the following detailed description are exemplary, and are intended to provide further explanation of the present disclosure as claimed. Other advantages and features of the present disclosure will be apparent from the following description, drawings and claims.
The present disclosure can be more fully understood by reading the following detailed description of the embodiment, with reference made to the accompanying drawing as follows:
Reference will now be made to the drawing figures to describe the present disclosure in detail. It will be understood that the drawing figures and exemplified embodiments of present disclosure are not limited to the details thereof.
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The control module 2 includes a power switch 20 and a controller 22. The power switch 20 is coupled between the rectifier 1 and the power capacitor C. The controller 22 is coupled a control end of the power switch 20, and provides a control signal Sc to control turning on and turning off the power switch 20 according to the lighting command C1 so as to convert (switch) the DC voltage Vdc to carry signals on the DC voltage (i.e., the carrier signals Scr) by turning on and turning off the power switch 20. In particular, the controller 22 may not include a traditional lighting signal generator, and generates the carrier signals Scr with changes in high-level voltage and low-level voltage by controlling turning on or turning off the power switch 20.
Since the carrier signals Scr are mostly composed of pulses with different widths, the width represents a specific logic meaning. Since the pulses with different widths are affected by the charging and discharging of the power capacitor C to generate different charge-discharge characteristics, the LED module 30 is designed to identify the charge-discharge characteristic of the capacitive charge-discharge signals Scd is a first logic (for example but not limited to logic “0”), a second logic (for example but not limited to logic “1”), or a latch indication (which is usually at the end of a pulse for indicating that the LED module 30 can perform a latch operation). Therefore, the drive command corresponding to the carrier signals Scr is generated according to the first logic, the second logic, and the latch indication to control lighting behavior of the LED 32 of the LED module 30. In particular, the drive command includes at least one of an address data and a lighting data. The address data and the lighting data may be selectively cooperated according to actual needs, for example, only the lighting data is provided or both the address data and the lighting data are provided.
The address data designates to at least one LED module 30. When the at least one LED module 30 is singular, the address data designates to the only LED module 30. When the at least one LED module 30 is plural, the address data may designate to one or more of the LED modules 30. The lighting data designates to the lighting behavior of the at least one LED module 30. When the at least one LED module 30 is singular, the lighting data designates to the lighting behavior of the only LED module 30. When the at least one LED module 30 is plural, the lighting data designates to the lighting behavior of one or more of the LED modules 30.
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Moreover, the LED module 30 includes at least two manners for identifying the charge-discharge characteristic. The first one is that the LED module 30 uses a predetermined threshold to identify the charge-discharge characteristic, and the second one is that the LED module 30 uses a time width to identify the charge-discharge characteristic. For identifying the charge-discharge characteristic by the predetermined threshold, the detection circuit 34 is used to compare the capacitive charge-discharge signals Scd with the predetermined threshold. Specifically, the detection circuit 34 sets a first threshold, a second threshold, and a third threshold, and the first threshold is the largest one and the third threshold is the smallest one. When a voltage value of the capacitive charge-discharge signals Scd triggers the first threshold, the second threshold, and the third threshold, the detection circuit 34 correspondingly generates a first logic signal, a second logic signal, and a third logic signal (the logic signals belong to the logic signal Slg). The logic circuit 36 identifies that the logic signal Slg is the first logic, the second logic, or the latch indication according to the first logic signal, the second logic signal, and the third logic signal. For example, when the first logic signal, the second logic signal, and the third logic signal appear in sequence within a certain time, it can be determined that the capacitive charge-discharge signals Scd refer to the latch indication (and so on).
For identifying the charge-discharge characteristic by the time width, the detection circuit 34 is used to generate charge time width and discharge time width of charging and discharging the capacitive charge-discharge signals Scd to the same voltage level. Specifically, the detection circuit 34 sets a predetermined threshold, and correspondingly generates the logic signal Slg when the capacitive charge-discharge signals Scd are discharged to be less than or equal to the predetermined threshold and the capacitive charge-discharge signals Scd are charged to be greater than or equal to the predetermined threshold. The logic circuit 36 identifies that the logic signal Slg is the first logic, the second logic, or the latch indication according to the time width of the logic signal Slg. For example, with the longest time width, it may be determined that the capacitive charge-discharge signals Scd refer to the latch indication (and so on).
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In one embodiment, the manner of identifying the charge-discharge characteristic by the predetermined threshold is not limited to the above-mentioned examples. Any manner of identifying the charge-discharge characteristic by the predetermined threshold should be included in the scope of the present disclosure. In addition, the time widths corresponding to the logic “0” and the logic “1” may also be swapped with each other. For example, the logic circuit 36 generates the first logic “1” but not limited to the logic “0” according to the logic signal Slg having only the first logic signal Slg1. In one embodiment, the latch indication “LK” may express that the capacitive charge-discharge signals Scd having longer discharging time or express that the capacitive charge-discharge signals Scd having longer high-level time.
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In one embodiment, the manner of identifying the charge-discharge characteristic by the time width is not limited to the above-mentioned examples. Any manner of identifying the charge-discharge characteristic by the time width should be included in the scope of the present disclosure. In addition, the time widths corresponding to the logic “0” and the logic “1” may also be swapped with each other.
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In particular, the LED module 30 includes at least two manners for identifying the charge-discharge characteristic. The first one is that the LED module 30 uses a predetermined threshold to identify the charge-discharge characteristic, and the second one is that the LED module 30 uses a time width to identify the charge-discharge characteristic. For identifying the charge-discharge characteristic by the predetermined threshold, the capacitive charge-discharge signals Scd are compared with a first threshold V1, a second threshold V2, and a third threshold V3 to correspondingly generate the logic signal Slg. For identifying the charge-discharge characteristic by the time width, the logic signal Slg is correspondingly generated the capacitive charge-discharge signals Scd from being discharged to less than or equal to a predetermined threshold V or being charged to greater than or equal to the predetermined threshold V. Afterward, a drive command corresponding to the signals on the DC voltage is generated according to the first logic, the second logic, and the latch indication to control lighting behavior of the LED light string (S160). In one embodiment, the logic circuit 36 is used to generate the drive command Cd corresponding to the carrier signals Scr according to the first logic, the second logic, and the latch indication. Afterward, a controller 38 is used to store the drive command Cd in a memory unit (not shown) inside the controller 38. Therefore, after all the LED modules 30 in the LED light string 3 have latched the drive commands Cd, the drive commands Cd are used to control lighting behavior of the LED light string 3.
In order to avoid the rough edges or switching surges produced by the capacitive charge-discharge signals Scd from affecting the accuracy of the detection circuit 34 on the capacitive charge-discharge signals Scd, after the step (S120), noise of the capacitive charge-discharge signals is filtered (S180). In one embodiment, a filter circuit 40 is used to filter noise of the capacitive charge-discharge signals Scd to avoid the rough edges or switching surges from affecting the accuracy of the detection circuit 34 on the capacitive charge-discharge signals Scd.
Although the present disclosure has been described with reference to the preferred embodiment thereof, it will be understood that the present disclosure is not limited to the details thereof. Various substitutions and modifications have been suggested in the foregoing description, and others will occur to those of ordinary skill in the art. Therefore, all such substitutions and modifications are intended to be embraced within the scope of the present disclosure as defined in the appended claims.
