Certain inventive techniques herein relate to illumination apparatuses or systems, such as string or rope lights, although they may be applicable to any of a variety of different illumination apparatuses or systems. In particular, certain inventive techniques disclose ways to control the color of a plurality of light sources without having additional conductor(s) to communicate control signal(s).
According to certain inventive techniques, an illumination system includes a plurality of distributed units. Each of the plurality of distributed units includes a light source and a light-source controller. The plurality of light sources is configured to simultaneously emit a selected type of light (e.g., first, second, or third type). The system also has a primary controller, which includes a voltage converter, power-voltage-delivering circuitry, an input (e.g., a wireless receiver or a local, wired input, such as a switch), and power-sequence-controlling circuitry. The voltage converter is configured to receive a first voltage and output a second voltage. The power-voltage-delivering circuitry is configured to receive the second voltage and deliver a LOW (e.g., zero volts) or HIGH power voltage to the plurality of distributed units simultaneously. The input is configured to receive a selection signal corresponding to one of the selected light types. The power-sequence-controlling circuitry is configured to cause the power-voltage-delivering circuitry to automatically transition the power voltage between LOW and HIGH in different sequences corresponding to the type of selected light. Each of the plurality of light-source controllers is configured to detect the power voltage (e.g., a DC voltage) provided to the corresponding distributed unit, cause the corresponding light source to emit the selected light type upon receiving the corresponding sequence while the power voltage is HIGH and at a constant voltage.
The system may also include a wireless remote control configured to wirelessly transmit the selection signal to the input (e.g., a wireless receiver). The selected type of light may include one of a plurality of predetermined colors and/or predetermined effects. Each of the light-source controllers may not include a processor.
Each of the plurality of light-source controllers may further include: monitoring circuitry configured to detect voltage transitions in the power voltage; command-framing circuitry configured to latch the voltage transitions; and command-interpreting circuitry configured to trigger pulse-width modulation circuitry, wherein the pulse-width modulation circuitry (for example, circuitry that generates a plurality (e.g., 3) of PWM outputs) is configured to control the light source (e.g., three lamps, each controlled by a different PWM output). Each of the plurality of distributed units may include a capacitor configured to provide an operating voltage to a given light-source controller for a predetermined time when the power voltage is LOW.
Each of the plurality of distributed units may be arranged in series, parallel, or a combination thereof. According to one technique: the plurality of distributed units is divided into a plurality of segments including a subset of the plurality of distributed units; each of the plurality of distributed units in the subset is arranged in series with each other; and the plurality of segments is arranged in parallel with each other.
Each of the plurality of light sources may include a plurality of differently-colored light-emitting diodes (LEDs). Each of the plurality of distributed units may include a voltage regulator configured to regulate the power voltage to a regulated voltage provided to the respective light-source controller. Each of the plurality of light-source controllers may be configured to use pulse-width modulation to cause the respective light source to emit the selected type of light.
According to one technique, the power voltage is LOW for a maximum duration during automatic transitioning, the maximum duration is sufficiently short (e.g., less than 10 mS) such that the human eye cannot perceive that the plurality of light sources have stopped emitting light.
The foregoing summary, as well as the following detailed description of certain techniques of the present application, will be better understood when read in conjunction with the appended drawings. For the purposes of illustration, certain techniques are shown in the drawings. It should be understood, however, that the claims are not limited to the arrangements and instrumentality shown in the attached drawings.
Some illumination apparatuses (e.g., rope light or string light) have, at each distributed light location, a plurality of lamps (e.g., different color lights, such as red, green, and blue). In some places of this disclosure and in the art, the collection of lamps can be referred to as a light source (even though there are actually three different colors (e.g., three different-colored LEDs). By controlling these lamps differently, different colors or color combinations can be achieved. According to certain inventive techniques, such control can be achieved without having additional “control” conductors. In other words, the colors of the lights can be changed using the two existing conductors—power and common.
According to one inventive technique, at each light location, there is circuitry that controls how the light sources are driven based on a current state. As the state is advanced, the colors change according to a predefined pattern. In addition to the color specified by a given state, behavior or effect of the lights may also be specified—e.g., dimming, swelling, flickering, flashing, variable effects and/or colors (different effects and/or colors to all or a subset of the light sources), random effects and/or colors, etc.
There may also be a capacitor at each light location that can temporarily provide operating power to the local control circuitry (but not necessarily the light sources) when power is momentarily switched off or sufficiently low. This control circuitry may sense that there is no power (or a LOW power voltage) on the power conductor and advances the state. When power is reapplied before the capacitor has discharged too much, the lights will be controlled in a way associated with the new state. If power is removed (or lowered) for a sufficiently long duration that the control circuit can no longer operate (i.e., the capacitor has discharged too much), the control circuit may reset to a default state.
In operation, power sequencing to advance states may occur very rapidly—even so rapidly that the changing color/behavior of the lights may not detectible by the human eye. Sequencing may be performed by a high-speed device, such as a transistor (e.g. MOSFET or BJT). The capacity of the capacitor may determine acceptable sequencing speeds to advance states or return to a default state. For example, interruptions of HIGH power for less than 250 mS (or as low as 30 mS or lower) may cause state advances while an interruption greater than 250 mS may result in the control circuitry returning to the default state.
The control circuitry may or may not include a processor (that uses volatile or nonvolatile memory to track states). According to one technique, a state machine including flip-flops may be used in lieu of a processor.
According to another technique, a message is encoded in power switching. The message may be encoded by the number and/or duration of pulses in the sequence. The control circuitry may receive and decode the message and implement a state or light type accordingly.
It may also be possible to create different colors/effects for different lights in the same string at the same time. For example, if power sequencing is above a certain speed, some control circuits may recognize the interruptions, and some may not. By exploiting this imperfection, different lights may have different colors/behaviors at the same time. Alternatively or additionally, noise may be injected on the power conductor or return to create random-type effects and colors. The randomization technique may be repeated, for example at a given rate (e.g., 0.2, 0.5, 1, 2, 4, or 8 seconds). The rate may also be variable.
Another way to create variable-type effects is to design the control circuitry (e.g., light-source controller 230 discussed below) to detect different transition durations or reset after different transition durations. The light-source control circuitry 230 from light source to light source may be configured differently (e.g., the power-providing capacitor may vary from one control circuitry to the next or the logic may be configured differently). This may enable color and/or effect variation.
Other additional features main include cycling colors and/or effects for all of the light sources at a given rate (or a random or variable rate). It may also be possible to pause cycling and/or variability or randomization. Another possible feature is an automatic shutoff and/or turn-on timer. Such a timer may be selected by a user. A 24 hour period may be divided up, such that the lights are ON for a first duration (e.g., 5 hours or 10 hours) and OFF for a second duration (e.g., 19 hours or 14 hours), and then repeating the cycle. The illumination apparatus may provide visual feedback to the operator that a timer mode has been entered (e.g., blink once for the 5/19 hour timer or twice for the 10/14 hour timer). The timing period may be resettable by the user.
Another possibility is to automatically shut off after a period of time (e.g., 8 hours). Unlike the previously-described mode, there may be no repeating of an ON/OFF timing cycle. The illumination apparatus may provide visual feedback (e.g., three blinks) such that the operator may know such a mode has been entered.
Each distributed unit 200 may include a light source 210 and a light-source controller 220. The distributed units 200 may be grouped together into a plurality of segments 230. Within a given segment, the distributed units 200 may be in series. The segments 230 may be arranged in parallel with each other. According to this arrangement, the portion of the illumination system containing the distributed units 200 may not have more than three wires in its thickness.
As depicted in
Distributed units 200 may be located at approximately one inch intervals. A strand may contain 4 segments 230 with 30 distributed units 200 each at one inch intervals for a total length of 10 feet, although other lengths/number of segments 230/number of distributed units 200/interval spacings are possible. Strands can be connected together with each other, for example, 10 to 15 strands may be connected together. For example, if a strand is 10 feet, a combination of strands could be 100 up to 150 feet. Multiple strands may be connected in series. In this configuration, all of the distributed units 200 in all of the strands could be powered from the same primary controller 100. The distributed units 200 within a given strand may be arranged in other manners. For example, all of distributed units 200 may be arranged in series. Alternatively, all of the distributed units 200 may be arranged in parallel.
When distributed units 200 are arranged in series, there may be a voltage drop across each distributed unit 200. Therefore, the voltage received by a given unit may be less than the power voltage output by the power-voltage-delivering circuitry 140. Even so, it is to be understood that the power voltage from the power-voltage-delivering circuitry 140 is being delivered to each distributed unit 200, even if that voltage has dropped off from its maximum at a given unit that is not first in the series.
Each light-source controller 220 may control its corresponding light source 210 according to the predetermined sequence of LOW/HIGH transitions on the power conductor. The light-source controller 220 may selectively switch or adjust power provided to the lamp(s) in the light source 210 to control the brightness of the lamp(s).
The exterior tube 240 may be connected to connectors at one or both ends of the strand. The primary controller 100 may be connected and/or mated to one end connector of the strand. The circuitry of the primary controller 100 may be enclosed in a casing (e.g., may include a polymer such as ABS). The casing (not shown) may have a connector on one side to make a connection to the light strand and a power cable on the other side to make connection to a power outlet.
When power is delivered through the power conductor, all of the light sources 210 may simultaneously emit a selected type of light. The light type may be communicated to the light-source controllers 220 by a predetermined sequence of switching power voltage on the power conductor. Upon receipt of the sequence, the light-source controllers 220 may control their respective light sources 210 to cause them to emit the selected type of light. A different predetermined sequence may correspond to a different predetermined type of light.
There may be various selected types of light—for example, three or more. Examples of types of light are different light colors and/or different light effects. Examples of light colors include red, pink, purple, white, blue, cyan, or green. Examples of light effects include the light source 210 blinking (for example, in a predetermined pattern), flashing, roaming colors, fading in, fading out, or the like, or any combination thereof. For example, a first type of light could be a static blue light. A second type of light could be a flashing red light. A third type of light could be a static white light. Of course, there are many different possibilities for a given type of light.
Each light source 210 may include a plurality of lamps (for example LEDs) each having a different color. According to one technique, a light source 210 has three LEDs of different colors (for example, red, green, and blue). By adjusting the intensities of the differently-colored lamps, it may be possible to create combined light with numerous possible colors. Each LED may be encapsulated in the same package, or they may be in different packages. The light-source controller 220 may also be encapsulated in the package with the LEDs, or it may be separately packaged.
The first-stage rectifier 110 and the first second-stage rectifier 120, together, may be a type of voltage converter, in that it receives a first voltage (e.g., 110 VAC) and outputs a second voltage (e.g., 170 VDC). Other circuitry and/or voltages may be possible for a voltage converter. The first second-stage rectifier 120 may provide the second voltage to the power-voltage-delivering circuitry 140.
The power-voltage-delivering circuitry 140 may receive the voltage from the first second-stage rectifier 120 and provide it to the distributed units 200. The power-voltage-delivering circuitry 140 may include the processor, R6-R10, and Q1-Q3. Transistors Q1-Q3 are shown as BJTs, but it may be possible to use MOSFETs as well. The power-voltage-delivering circuitry 140 may be controlled by two outputs on the processor.
Power to the distributed units 200 may be provided by the power-voltage-delivering circuitry 140 when the processor output signal passing through R8 and connected to the base of Q2 goes high (e.g., 5 VDC). This may cause Q2 to be conducting. As a result of Q2 becoming conducting, Q1 may also be conducting. At the same time, the processor output signal passing through the resistance R9 and connected to the base of Q3 may be low (e.g., 0 VDC), thereby causing Q3 to not be conducting. The previous conditions may all be respected, then the power at the output of the primary controller may be high (e.g., 170 VDC).
Power to the distributed units 200 may be discontinued by the power-voltage-delivering circuitry 140 when the output signal of the processor passing through R8 goes low. As a result, Q2 may not be conducting, thereby causing Q1 to not be conducting. At this time, the power conductor voltage may be floating. A short time thereafter (e.g., a few nanoseconds), the processor output signal passing through the resistance R9 and connected to the base of Q3 may go low, thereby causing Q3 to become conducting. The output of the controller may then be pulled down to a low voltage (e.g., 0.7 VDC).
The power-voltage-delivering circuitry 140 may deliver a LOW or HIGH power voltage to the plurality of distributed units 200 simultaneously. Examples of a LOW power voltage may be zero volts or a relatively low voltage level (e.g., 0.7 VDC). Examples of a HIGH power voltage may be (e.g., 170 VDC). The level of the HIGH power voltage may determine how many distributed units 200 can be sufficiently powered. The reference voltage inside each distributed unit may be 5 VDC and 30 distributed units 200 may be assembled in a segment. Furthermore, 4 segments may be assembled in a rope light. The primary controller may be capable of providing the current supplied to 10 rope lights (e.g., a total of 1200 distributed units). It may be possible for the power-voltage-delivering circuitry 140 to vary the HIGH power voltage to adjust the brightness level for each of the light sources 210. Such variance may be controlled by the power-sequence-controlling circuitry 150.
The second second-stage rectifier 130 may provide power (e.g., low-voltage DC power) to the power-sequence-controlling circuitry 150. The second second-stage rectifier 130 may include R5 (e.g., 1 MΩ), C2 (e.g., 1 μF rated up to 400 VDC), D6 (e.g., 4007-type diode), D7 (e.g. 4.7 V Zener), C3 (e.g., 100 μF), and/or C4 (e.g., 0.1 μF). The second-stage rectifier may output power to the processor. The diode D7 may be a Zener diode and may maintain the voltage to a level acceptable for the processor. The diode D6 may be protecting the circuitry from having reverse current if the voltage drops at the output of the first-stage rectifier 110. C4 may act as decoupling capacitor to reduce noise at the processor. C3 may function with the Zener diode to improve voltage stabilization at the processor. R5 and C2 may act together as low pass filter.
The power-sequence-controlling circuitry 150 may cause the power-voltage-delivering circuitry 140 to automatically transition the power voltage between LOW and HIGH in different sequences corresponding to the selected type of light.
The power-sequence-controlling circuitry 150 may include a processor (MCU) and/or related circuitry. The processor may include inputs and/or outputs to accomplish various functions. For example, the processor may receive a switch signal input from SW1, to indicate that power to the distributed units 200 is to be turned on or off. SW1 may be actuated by a user, for example, when it is desired to activate the light system or to turn it OFF altogether.
The power-sequence-controlling circuitry 150 may also have an input that receives a selection signal. The selection signal may be determined by a user interface (not shown). Through the interface, a user may select a given light type, and based on that selection, an appropriate selection signal may be generated and transmitted to the power-sequence-controlling circuitry 150. Possible selection signals include: turn all the light sources 210 ON; turn all the light sources 210 OFF; select a color (e.g., blue, green, purple, etc.) for static display (i.e., constant color at constant brightness); cycle colors of the light sources 210 every X seconds; randomize colors of the light sources 210; vary colors of the light sources 210 among subsets of a strand; randomize colors of the light sources 210 every X seconds; vary colors of the light sources 210 among subsets of a strand; pause color cycling of the light sources 210; pause color randomization of the light sources 210; pause randomization cycling of the light sources 210; enable timer mode(s); enable auto shut-off mode; cause light effects of the light sources 210, such as dim, color roam, flash; randomize light effects of the light sources 210; randomize color and light effects of the light sources 210; vary color and/or light effects of the light sources amongst subsets in a given strand; change repeat rate of light effects to X seconds; increase the value of X; and/or decrease the value of X.
The user interface may be on the illumination apparatus itself. It may also be on a wired or physically tethered component. The user interface may also be on a wireless device (not shown). The wireless device (or remote control) may communicate with the illumination apparatus with infrared light, Bluetooth, WiFi, or the like. In such a case, the primary controller 100 may include a wireless receiver. An example of such a wireless receiver is D9, an infrared photodetector, for use with an infrared remote control. Other types of wireless receivers include Bluetooth, WiFi, or the like. The received selection signal may be communicated to the processor, where it is decoded and control of an appropriate power sequence is initiated by the power-sequence-controlling circuitry 150.
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According to one technique, different light-source controllers 220 in a given strand may recognize different reset durations. In this way, the light-source controllers 220 may be separately “addressed” by the primary controller 100, such that a given light-source controller 220 may be able to recognize a reset command which is not recognizable by at least one other light-source controller 220 in a strand. One way to achieve selective communication between the primary controller 100 and a given light-source controller 220 is to configure the light-source controllers 220 to recognize different reset period durations
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According to one technique, different light-source controllers 220 may be configured differently to recognize different reset periods, such that the different light-source controllers can be separately addressed by the primary controller 100. For example, a first light-source controller 220 may recognize a reset when the power voltage is maintained low for 4 clock periods, while a second light-source controller 220 may recognize a reset when the power voltage is maintained low for 5 clock periods. In a given strand (or in different strands), there may be a number of light-source controllers 220 that recognize a first duration period as a reset command and a number of different light-source controllers 220 that recognize a second duration period as a reset command. This technique can be expanded such that it is possible to separately address three or more differently configured light-source controllers 220 in a given strand or in different strands.
After a reset command by the primary controller 100 (or even when no reset command has been issued), the circuitry 227 may add the transitions detected by the circuitry 221. The circuitry may perform the addition using three flip-flops. Based on how many transitions are detected, the circuitry may adjust the outputs (as shown, A0, A0B, A1, A1B, A2, or A2B). If three flip-flops are used, it may be possible to provide 8 different output states (based on 3 bits). The number of possible output states may be increased or decreased by, for example, changing the number of flip-flops that are used.
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Following the reset period, the latched light type may be a default light type (by circuit design). Each transition following the reset may move the selection to the next light type of the cycle hardcoded in the matrix of circuitry 228. Since light types may be seen as states in a loop, the distributed units may operate without reset transition before each light type sequence. The reset may ensure that all distributed units 200 are set to the same default light type and none is set to a different light type (for example, due to an undesirable noise event).
As discussed above, according to certain techniques, different light-source controllers 220 may be configured to recognize different durations to be reset periods. This may be one way to create variable colors and/or effects amongst light-source controllers 220 in a given strand or across multiple strands. For example, a first type of light-source controller 220 may recognize a 4 clock period duration with a low voltage on the power conductor as a reset command. A second type of light-source controller 220 may recognize a 5 clock period duration with a low voltage on the power conductor as a reset command. After the 4 clock period reset command, a first type of transition sequence may be driven by the primary controller 100 on the power conductor. The first type of light-source controller 220 may respond to the first type of transition sequence, but not the second type of light-source controller 220. After the 5 clock period reset command, a second type of transition sequence may be driven by the primary controller 100 on the power conductor. The second type of light-source controller 220 may respond to the second type of transition sequence, but not the first type of light-source controller 220. Thus, the light-source controllers 220 may be separately addressed and instructed to cause different types of light types, thereby giving simultaneous variability of light types within a given strand or across multiple strands.
Each rope light strand may have a length between 10 to 15 feet, for example. A number of strands (for example 10-20 strands) may be connected end to end to create a long rope that may reach, for example, 100 feet. Electrically, each strand may be in series to the others. All the distributed units 200 from all the connected strands may receive power from the same primary controller 100.
It will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the novel techniques disclosed in this application. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the novel techniques without departing from its scope. Therefore, it is intended that the novel techniques not be limited to the particular techniques disclosed, but that they will include all techniques falling within the scope of the appended claims.
This application claims the benefit of U.S. Prov. Pat. Appl. No. 62/429,123, filed on Dec. 2, 2016, the entirety of which is herein incorporated by reference.
Number | Date | Country | |
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62429123 | Dec 2016 | US |