DEVICE FOR THE DETECTION OF A DIMMER PHASE ANGLE ESTABLISHED BY THE OPERATION OF A DIMMER FOR A SOLI

专利摘要:
device for detecting a dimmer phase angle established by operating a dimmer for a solid-state lighting load and method for detecting a dimmer phase angle established by operating a dimmer for a light-emitting diode device for detecting a dimmer phase angle established by operating a dimmer for a solid state lighting load includes a processor having a digital input, a first diode connected between the digital input and a voltage source and a second diode connected between digital input and ground. the device also includes a first capacitor connected between a digital input and a detection node, a second capacitor connected between the detection node and the ground, and a resistor connected between the detection n6 and a rectified voltage node, which receives a rectified voltage of the dimmer. the processor is configured to sample digital pulses on a digital input based on the rectified voltage and identify the dimmer phase angle based on the lengths of the sampled digital pulses.
公开号:BR112012011642A2
申请号:R112012011642-8
申请日:2010-04-13
公开日:2020-03-31
发明作者:Lys Ihor；campbell Gregory；Datta Michael
申请人:Koninklijke Philips Electronics N. V.；
IPC主号:

专利说明:

DEVICE FOR THE DETECTION OF A DIMMER PHASE ANGLE ESTABLISHED BY THE OPERATION OF A DIMMER FOR A SOLID STATE LIGHTING LOAD AND METHOD FOR THE DETECTION OF A DIMMER PHASE ANGLE ESTABLISHED BY A DIMMER OPERATION OF ONE DIMMERISATION OF ONE DIMMER OPERATION
CROSS REFERENCE WITH RELATED REQUESTS
This application claims priority of U.S. provisional patent application no. 61/262770, filed on November 19, 2009, and US provisional patent application no. 61/285580, filed on December 11, 2009, the disclosures of which are hereby incorporated by reference in their entirety.
TECHNICAL FIELD
The present invention is generally directed to the control of solid state luminaires. More particularly, various methods and equipment of the invention disclosed herein relate to the digital detection of the phase angle of dimmers and / or the presence of dimmers for solid-state lighting systems. Also, various methods and equipment of the invention disclosed herein refer to the selective determination of the input voltage of the solid state luminaires based on the detected phase angle of dimmers.
HISTORIC
Digital or solid-state lighting technologies, that is, lighting based on semiconductor light sources, such as light-emitting diodes (LEDs), offer a viable alternative to traditional fluorescent, high-intensity discharge (HID) lamps, and incandescent. The functional advantages and benefits of LEDs include high energy conversion efficiency and optical efficiency, durability, low operating costs and many others. Recent advances in LED technology have provided
2/56 efficient and solid full-spectrum lighting sources that allow for a variety of lighting effects in many applications.
Some of the luminaires that configure these sources have a lighting module, including one or more LEDs capable of producing white and / or different light colors, eg red, green and blue, as well as a controller or processor for the independent control of the production of LEDs in order to generate a variety of colors and luminous effects of color changes, for example, as discussed in detail in US patents Nos. 6,016,038 and 6,211,626. LED technology includes line voltage powered luminaires, such as those in the ESSENTIALWHITE series, produced by Philips Color Kinetics. These luminaires can be dimmable using the rear edge dimmer technology, such as low voltage (ELV) electric dimmers for 120VAC line voltages (or input supply voltages).
Many lighting applications make use of dimmers. Conventional dimmers work well with incandescent lamps (filament and halogen). However, problems occur with other types of electronic lamps, including compact fluorescent lamps (CFL), low voltage halogen lamps that use electronic transformers, and lamps for solid state lighting (SSL), such as LEDs and OLEDs. Low-voltage halogen lamps that use electronic transformers, in particular, can be dimmed using special dimmers, such as low voltage electrical type (ELV) dimmers or capacitive resistive dimmers (RC), which work properly with loads that have a circuit power factor correction (PFC) at input.
However, conventional state luminaires
3/56 solid, including white LED luminaires, are dependent on the input voltage. Thus, the various types of white solid-state luminaires operate only with specific line voltages for which they have been designed respectively. The values and frequencies of the line voltages may differ, depending on several factors, such as the geographic location of the user (eg, North American markets typically require 120VAC, 60 Hz line voltages, while European markets typically require line voltages of 230VAC, 50 Hz) and the physical location of the white solid-state lighting fixture installed (eg, luminaires installed in high alcoves usually require line voltages of 277VAC, while fixtures installed in environments under cabinets normally require line voltages of 120VAC).
These operational differences between various types of white solid-state luminaires cause confusion and practical inefficiencies for manufacturers and users. For example, electrical contractors should normally have multiple sets of equipment on hand corresponding to the number of different line voltages available on a given construction project. Equipment sets must be carefully managed during installation, or the new white LED luminaires may be impaired by applying an incorrect line input voltage. In addition, although white LED luminaires designed to operate at different line input voltages may have the same printed circuit boards, other components differ based on the design differences necessary to accommodate operation at 100VAC line input voltages , 120VAC, 230VAC or 277VAC, for example. This is inefficient from a manufacturing and supply chain perspective, as each
4/56 line entry requires its own special list of materials, units to keep in stock and the like. This administration proved to be problematic, since it is difficult to forecast demand. Therefore, marketing, supply chain and manufacturing would benefit from a white LED light or other solid state luminaire having a universal voltage input.
Also, conventional dimmers typically cut a portion of each waveform from the main input voltage signal and pass the rest of the waveform to the luminaire. A leading edge or forward phase dimmer cuts the leading edge of the voltage signal waveform. A rear edge or reverse phase dimmer cuts the rear edges of the voltage signal waveforms. Electronic loads, such as LED drivers, usually work best with rear-edge dimmers.
Incandescent devices and other conventional resistive lighting devices naturally respond without error to a cut sine wave produced by a phase cut dimmer. In contrast, LEDs and other solid-state lighting loads can incur some problems when placed on this phase-cut dimmer, such as low definition drop, triac trigger failure, minimum load problems, high definition flickering and large steps in luminous power. Some of these problems are dependent on the dimmer setting. Therefore, to solve these problems, it may be necessary to electrically determine the adjustment or phase angle to which the dimmer is set.
SUMMARY
The present disclosure is directed to the methods and devices of the invention for detecting a phase angle from a dimmer to a solid state luminaire or
5/56 luminaire, and determine the voltage input for the dimmer when the detected phase angle is above a determination limit setting and recover a previously determined voltage input when the phase angle is below the limit setting.
Generally, in one aspect, a device for detecting a dimmer phase angle established by operating a dimmer for a solid-state lighting load includes a processor having a digital input, a first diode connected between the digital input and a voltage source and a second diode connected between the digital input and the ground. The device also includes a first capacitor connected between the digital input and a detection node, a second capacitor connected between the detection node and the ground, and a resistor connected between the detection node and a rectified voltage node, which receives a rectified voltage of the dimmer. The processor is configured to sample digital pulses at the digital input based on the rectified voltage and identify the dimmer phase angle based on the lengths of the sampled digital pulses.
In another aspect, a method is provided to selectively provide a universal voltage input for a luminaire, including a dimmer, a power converter and a solid-state lighting load. The method includes detecting a phase angle of the dimmer and determining whether the detected phase angle is below a determination limit. When the phase angle detected is below the determination limit, a power setting of the power converter is determined based on a previously determined main input voltage value. When the detected phase angle is not below the determination limit, the main input voltage value is calculated and the power setting of the power converter is
6/56 determined based on the calculated value of the main input voltage.
In yet another aspect, a method is provided for detecting a dimmer phase angle established by operating a dimmer for an LED. The method includes receiving a digital input signal corresponding to a dimmerized rectified voltage from the dimmer, the dimerized rectified voltage having the signal waveform; detecting the rising edge of a pulse from a digital input signal corresponding to a rising edge of the signal waveform; sample the pulse periodically to determine a pulse length; and determining the phase angle of the dimmer based on the pulse length.
As used herein for the purposes of the present disclosure, the term LED is to be understood to include any electroluminescent diode or other type of carrier / junction based system that is capable of generating radiation in response to an electrical signal. Thus, the term LED includes, without limitation, various semiconductor structures that emit light in response to a current, light-emitting polymers, organic light-emitting diodes (OLEDs), electroluminescent tapes, and the like. In particular, the term LED refers to light emitting diodes of all types (including semiconductor diodes and organic light emitting diodes} that can be configured to generate radiation in one or more infrared spectrum, ultraviolet spectrum and various parts of the visible spectrum (usually including radiation wavelengths from approximately 400 nanometers to approximately 700 nanometers.) Some examples of LEDs include, without limitation, various types of infrared LEDs, ultraviolet LEDs, red LEDs, blue LEDs, green LEDs, yellow LEDs, amber LEDs , Orange LEDs, and white LEEs (more discussed below).
7/56 it is appreciated that LEDs can be configured and / or controlled to generate radiation having various bandwidths (eg, total widths at maximum medium or FWHM) for a given spectrum (eg, narrow bandwidth, width broadband), and a variety of dominant bandwidths within a given general color categorization.
For example, an embodiment of an LED configured to generate essentially white light (e.g., a white LED fixture) may include a number of arrays that respectively emit different spectra of electroluminescence that, in combination, mix to form essentially light white. It was another realization, a white light LED luminaire can be associated with a phosphorescent material that converts electroluminescence having a first spectrum to a different second spectrum. In one example of an embodiment, the electroluminescence having a relatively short wavelength and narrow bandwidth spectrum pumps the phosphorescent material, which in turn radiates radiation of greater wavelength having a somewhat broader spectrum.
It should also be understood that the term LED does not limit the type of physical and / or electrical package of an LED. For example, as discussed above, an LED can refer to a simple light-emitting luminaire having multiple arrays that are configured to respectively emit different radiation spectra (eg, which may or may not be individually controllable). Also, an LED can be associated with a phosphorescent material that is considered an integral part of the LED (eg, some types of white LEDs). In general, the term LED can refer to packaged LEDs, non-packaged LEDs, surface mount LEDs, chip-on-board LEDs, T-pack LEDs, radial pack LEDs, power pack LEDs, LEDs
8/56 including some types of wraps and / or optical element (eg a diffusing lens), etc.
The term light source should be understood as referring to any one or more variety of radiation sources, including, without limitation, LED based sources (including one or more LEDs as defined above), incandescent sources (eg, light bulbs). filaments, halogen lamps), fluorescent sources, phosphorescent sources, high intensity discharge sources (eg sodium vapor lamps, mercury vapor and metal halide), lasers, other types of electroluminescent sources, pyroluminescent sources (eg ., flames), velaluminescent sources (eg gas blankets, carbon arc radiation sources), photoluminescent sources (eg, gas discharge sources), luminescent cathode sources using electronic satiation, galvanoluminescent sources, crystalloluminescent sources , cineluminescent sources, thermoluminescent sources, triboluminescent sources, sonoluminescent sources, radioluminescent sources and luminescent polymers.
A given light source can be configured to generate electromagnetic radiation within the visible spectrum, outside the visible spectrum, or a combination of both. Thus, the terms light and radiation are used interchangeably here.
In addition, a light source may include as an integral component one or more filters (eg, colored filters), lenses, or other optical components. It should also be understood that light sources can be configured for various applications, including without limitation, indication, display, and / or lighting. A light source is a light source particularly configured to generate radiation having sufficient intensity to illuminate
9/56 effectively an indoor or outdoor space. In this context, sufficient intensity refers to sufficient radiant energy in the visible spectrum generated in space or environment (the lumens unit is generally used to represent the total light power of a light source in all directions, in terms of radiant energy or light flux) to provide ambient lighting (that is, light that can be perceived indirectly and that can, for example, be reflected by one or more varieties of intervening surfaces before being perceived in whole or in part).
The term luminaire is used here to refer to the realization or arrangement of one or more lighting units in a given factor, assembly or shape package. The term lighting unit is used herein to refer to equipment that includes one or more light sources of the same or different types. A given lighting unit can have any variety of mounting arrangements for the light source (s), arrangements and forms of enclosure / housing and / or electrical and mechanical connection configurations. Additionally, a given lighting unit can optionally be associated with (eg, include, be coupled and / or packaged with) various other components (eg, control circuits) related to the operation of the light source (s) ). An LED-based lighting unit refers to a lighting unit that includes one or more LED-based light sources as discussed above, individually or in combination with other non-LED-based light sources. A multichannel lighting unit refers to an LED-based or non-LED-based lighting unit that includes at least two light sources configured to generate different radiation spectra, each with a different source of radiation.
10/56 spectrum can be called the channel of the multichannel lighting units.
The term controller is currently used to describe various equipment related to the operation of one or more light sources. A controller can be constituted in several ways (for example, with dedicated hardware) to carry out various functions discussed herein. A processor is an example of a controller that employs one or more microprocessors that can be programmed using software (eg, microcode) to perform various functions discussed herein. A controller can be made with or without the use of a processor, and it can also be made up of a combination of dedicated hardware to perform some functions and a processor (eg, one or more programmed microprocessors and associated circuits) to perform other functions . Examples of controller components that can be employed in various embodiments of the present disclosure include, without limitation, conventional microprocessors, application-specific integrated circuit microcontrollers (ASICs), and field programmable ports (FPGAs).
In various embodiments, a processor and / or controller can be associated with one or more storage media (generically referred to in the present memory, eg, volatile and non-volatile computer memory as random access memory (RAM), memory only read-only (ROM), read-only programmable memory (PROM), and electrically programmable read-only memory (EPROM), electrically removable and programmable read-only memory (EEPROM), universal serial bus (BUS) drive, floppy disks, disks compact discs, optical discs, magnetic tapes, etc.). In some achievements, the media
11/56 storage can be coded with one or more programs that, when executed on one or more processors and / or controllers, perform at least some of the functions discussed in the present. Various storage media can be fixed inside a processor or controller or can be transported, so that one or more programs stored therein can be loaded into a processor or controller in order to carry out various aspects of the present invention discussed in the present. The terms program or computer program are used here in a generic sense to refer to any type of computer code (eg, software or microcode) that can be used to program one or more processors or controllers.
In a network embodiment, one or more luminaires coupled to a network can serve as a controller for one or more other luminaires coupled to the network (eg, in a master / slave relationship). In another embodiment, a networked environment may include one or more dedicated controllers that are configured to control one or more of the luminaires attached to the network. Generally, multiple luminaires individually attached to the network can have access to the data that is present in the medium or in the media, · however, a given luminaire can be addressable because it is configured to selectively exchange data with (that is, receive data from, and / or transmit data to) the network, based, for example, on one or more certain identifiers (eg addresses) assigned to it.
The term network as used herein refers to any interconnection of two or more luminaires (including controllers or processors) that facilitate the transport of information (eg for luminaire control, data storage, data exchange, etc.) between any two or more
12/56 luminaires and / or between multiple luminaires coupled to the network. As should be readily appreciated, various network designs suitable for interconnecting multiple luminaires can include any variety of network topology and employ any variety of communications protocols. Additionally, in various networks according to the present disclosure, any connection between two luminaires can represent a dedicated connection between the two systems, or alternatively a non-dedicated connection. In addition to carrying information for two luminaires, this non-dedicated connection can carry information not necessarily dedicated to either of the two luminaires (eg, an open network connection). In addition, it should be readily appreciated that various networks of luminaires as discussed herein may employ one or more wireless, wire / cable and / or fiber optic links to facilitate the transport of information on the network.
It should be appreciated that all combinations of the concepts presented and other concepts discussed below in greater detail (provided these concepts are not mutually inconsistent) are contemplated as part of the subject of the invention disclosed herein. In particular, all combinations according to the subject claimed that appear at the end of this disclosure are contemplated as being part of the subject of the invention disclosed herein. It should also be appreciated that the terminology explicitly employed herein and which also appears in any disclosure incorporated by reference must conform to a meaning more consistent with the concepts particularly disclosed herein.
BRIEF DESCRIPTION OF THE DRAWINGS
In the drawings, similar reference characters generally refer to the same parts in all views.
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Also, the drawings are not necessarily to scale, emphasis is usually placed on illustrating the principles of the invention.
FIGURE 1 is a block diagram showing a dimmable lighting system, including a solid state luminaire and a phase detector, according to a representative embodiment.
FIGURE 2 is a circuit diagram showing a dimming control system, including a phase detection circuit according to a representative embodiment.
Figures 3A-3C show sample waveforms and corresponding digital pulses from a dimmer, according to a representative embodiment.
FIGURE 4 is a flow chart showing a process for detecting the phase angle of a dimmer, according to a representative embodiment.
FIGURE 5 shows sample waveforms and corresponding digital pulses from a solid state luminaire with and without a dimmer, according to a representative embodiment.
FIGURE 6 is a flow chart showing a process for detecting the presence of a dimmer, according to a representative embodiment.
FIGURE 7 is a circuit diagram showing a dimming control system, including a solid state luminaire and a phase detection circuit, according to a representative embodiment.
FIGURE 8A shows sample waveforms from a dimmer having one level in adjustment above of a limit in determination, in wake up with an achievement representative.FIGURE 8B shows shapes sample waves of one dimmer having one level in adjustment below of a limit in determination, in wake up with an achievement representative.
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FIGURE 9 is a flow chart showing a process for determining the main input voltage using a detected phase angle of a dimmer, according to a representative embodiment.
FIGURE 10 is a block diagram showing a lighting system, including a solid state luminaire and an input voltage controller according to a representative embodiment.
FIGURE 11 is a block diagram of a controller of an input voltage controller, according to a representative embodiment.
FIGURE 12 is a flow chart showing a process for controlling the power of a solid state luminaire, according to a representative embodiment.
FIGURE 13 is a flow chart showing a process for determining a voltage value of an input main voltage signal, according to a representative embodiment.
FIGURE 14 is a flow chart showing a process for detecting peaks in a waveform of the input main voltage signal, according to a representative embodiment.
FIGURE 15 is a flow chart showing a process for determining the slopes of a waveform of the input main voltage signal, according to a representative embodiment.
Figures ISA and 16B are sample traces of waveforms of non-dimerized and dimerized main input voltage signals.
FIGURE 17 is a graph showing sample slopes corresponding to non-dimerized and dimerized input voltage main signal waveforms.
DETAILED DESCRIPTION
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In the following detailed description, for the purpose of explanation and not limitation, representative achievements that reveal specific details are presented in order to provide a general understanding of the present teachings. However, it will be apparent to those skilled in the art who have had the benefit of the present disclosure, that other achievements in accordance with the present teachings that deviate from the specific details disclosed herein remain within the scope of the appended claims. In addition, descriptions of well-known equipment and methods can be omitted in a way that does not obscure the description of representative achievements. These methods and equipment are clearly within the scope of the present teachings.
Depositors recognized and appreciated that it would be beneficial to provide a circuit capable of detecting the level of dimerization (dimmer phase angle) in which a dimmer is adjusted for a solid state luminaire. Depositors also recognized and appreciated that it would be beneficial to provide a circuit capable of detecting the presence (or absence) of a dimmer for a solid-state luminaire.
In addition, Depositors recognized and appreciated that it would be beneficial to provide universal power for solid state luminaires using several different main input voltages, such as 100VAC, 120VAC, 208VAC, 230VAC and 277VAC, and that it would be beneficial to accurately determine the value of main input voltage when a dimmer setting is above a determination limit or phase angle.
FIGURE 1 is a block diagram showing a dimmable lighting system, including a solid state luminaire and a phase angle detector, according to a representative embodiment.
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With reference to FIGURE 1, a dimmable lighting system 100 includes a dimmer 104 and a rectification circuit 105, which provides a rectified Urect voltage (dimmerized) from voltage input 101. Voltage input 101 can provide different main non-rectified voltages input, such as 100VAC, 120VAC, 230VAC and 277VAC, according to various constitutions. The dimmer 104 is a phase cut dimmer, for example, which provides dimming capability by cutting the leading edges (leading edge dimmer) or the rear edges (rear edge dimmer) of the voltage signal waveforms of the voltage input 101 in response to the vertical operation of your cursor 104a. Generally, the magnitude of the Urect rectified voltage is proportional to a phase angle established by dimmer 104, so that a smaller phase angle results in a lower Urect rectified voltage. In the example shown, it can be assumed that the cursor is moved downwards to a smaller phase angle, reducing the light output by the solid state lighting load 140, and moved upwards to increase the phase angle, increasing the light output by solid-state lighting load 140.
The dimmable lighting system 100 further includes a phase angle detector 110 and a power converter 120. Generally, the phase angle detector 110 detects the phase angle of dimmer 104 based on the rectified Urect voltage. In various embodiments, the phase angle detector 110 can produce a power control signal, eg via a control line 129, to the power converter 120, as far as the phase angle detector 110 is configured to the control operation of the power converter 120. The power control signal can be a pulse code modulation (PCM) signal or other digital signal, for example, and can switch between high levels and
17/56 lows according to a duty cycle determined by the phase angle detector 110 based on the detected phase angle. The duty cycle can range from about 100 percent (eg, continuously at the high level) to about 5 percent (eg, continuously at the low level), and includes any percentage between, for example, properly set the power setting of the power converter 12 0 to control the level of light emitted by the solid state lighting load 140.
In various embodiments, the power converter 120 receives the rectified voltage Urect from the rectification circuit 105, and emits a corresponding continuous voltage to drive the solid state lighting load 140. The power converter 120 converts between the rectified voltage Urect and the 15 DC voltage based on at least the magnitude of the voltage output of the dimmer 104 by means of the rectifying circuit 105, eg, established by the operation of the cursor 104a. The production of DC voltage by the power converter 120 thus reflects the phase angle of the dimmer (i.e., the level of dimerization) applied by the dimmer 104.
FIGURE 2 is a circuit diagram showing a dimerization control system, including a dimmer phase angle detection circuit, according to a representative embodiment. The general components of FIGURE 2 25 are similar to those of FIGURE 1, although more details are provided with respect to the various representative components, according to an illustrative configuration. Of course, other configurations can be made without leaving the scope of the present teachings.
With reference to FIGURE 2, the dimming control system 200 includes a rectifying circuit 205 and a phase angle detection circuit of dimmer 210 (hatch box). As discussed above with respect to the
18/56 rectification 105, rectification circuit 205 is connected to a dimmer (not shown), indicated by the dim hot and dim neutral inputs to receive ungrounded (dimmed) voltage from the voltage input (not shown). In the configuration shown, rectification circuit 205 includes four diodes D201-D204 connected between rectified voltage node N2 and earth. The rectified voltage node N2 receives the rectified voltage Urect (dimerized), being connected to earth by the input filter capacitor C215 connected in parallel to the rectifying circuit 205.
phase angle detector 210 detects the dimmer phase angle (dimer level) based on the rectified Urect voltage and, in various embodiments, can produce a power control signal from the PWM 219 output, eg to a converter power to control the LED load operation, discussed below with reference to FIGURE 7. This allows the 210 phase angle detector to selectively adjust the amount of power delivered from the main input to the LED load based on the detected phase angle .
In the representative embodiment shown, the phase angle detection circuit 210 includes a microcontroller 215, which uses waveforms of the rectified voltage Urect to determine the phase angle of the dimmer. Microcontroller 215 includes a digital input 218 connected between a first diode D211 and a second diode D212. The first diode D211 has a ring connected to a digital input 218 and a cathode connected to the voltage source Vcc, and the second diode 112 has a ring connected to earth and a cathode connected to a digital input 218. The microcontroller 215 also includes a digital output, such as the PWM 219 output.
In various embodiments, the 215 microcontroller may be a PIC12F683 processor, produced by Microchip Technology, Inc., for example, although they may be
19/56 included other types of microcontrollers or other processors without departing from the scope of the present teachings. For example, the functionality of microcontroller 215 can consist of one or more processors and / or controllers, connected to receive a digital input between the first and second diodes D211 and D212 as discussed above, which can be programmed using software or firmware ( eg stored in a memory} to perform various functions, or they can be constituted as a combination of dedicated hardware to perform some functions and a processor (eg, one or more programmed microprocessors and associated circuits) to perform other functions Examples of controller components that can be employed in various embodiments include, without limitation, conventional microprocessors, microcontrollers, ASICs and FPGAs, as discussed above.
The phase angle detection circuit 210 also includes several passive electronic components, such as first and second capacitors C213 and C214, and a resistance indicated by the representative first and second resistors R211 and R212. The first capacitor C213 is connected between digital input 218 of microcontroller 215 and a detection node N1. The second capacitor C214 is connected between the detection node N1 and the ground. The first and second resistors R211 and R212 are connected in series between the rectified voltage node N2 and the detection node Nl. In the embodiment shown, the first capacitor C213 can have a value of about 560pF and the second capacitor C214 can have a value of about 10pF, for example. Also, the first resistor R211 can have a value of about 1 megaohm and the second resistor R212 can have a value of about 1 megaohm, for example. However, the respective values of the first and second capacitors C213 and C214, and the first and second
20/56 resistors R211 and R212 can vary to provide unique benefits for any particular situation or to meet the requirements of the specific design of the application of various achievements, as would be apparent to the technician in the subject.
The rectified Urect voltage (dimmerized) is alternately coupled to digital input 218 of microcontroller 215. The first resistor R211 and the second resistor R212 limit the current at digital input 218. When the signal waveform of the rectified Urect voltage rises, the first capacitor C213 is charged at the rising edge by means of the first and second resistors R211 and R212. The first diode D211 fixes on the digital input 218 a diode drop above the voltage source Vcc, for example, while the first capacitor C213 is charged. The first capacitor C213 remains charged as long as the signal waveform is not zero. At the falling edge of the Urect rectified voltage signal waveform, the first capacitor C213 discharges through the second capacitor C214, and digital input 218 is fixed to a diode drop below the ground by the second diode D212. When a rear edge dimmer is used, the falling edge of the signal waveform corresponds to the beginning of the cut portion of the waveform. The first capacitor C213 remains discharged as long as the signal waveform is zero.
Thus, the digital pulse of the resulting logic level at digital input 218 closely follows the movement of the cut rectified voltage Urect, examples that are shown in Figures 3A-3C.
More particularly, Figures 3A-3C show sample waveforms and corresponding digital pulses at digital input 218, according to representative embodiments. The upper waveforms in each figure
21/56 show the Urect rectified voltage cut, in which the amount of cuts reflects the level of dimerization. For example, waveforms may show a part of a total 170V peak (or 340V for the European Union), a rectified sine wave that appears at the output of the dimmer. The lower square waveforms show the corresponding digital pulses seen on digital input 218 of microcontroller 215. Notably, the length of each digital pulse corresponds to a cut-off waveform, and thus is equal to the amount of time that the internal switch of the dimmer is on. Receiving digital pulses through digital input 218, microcontroller 215 can determine the level at which the dimmer has been set.
FIGURE 3A shows Urect rectified voltage sample waveforms and corresponding digital pulses when the dimmer is at its highest setting, indicated by the upper position of the dimmer cursor shown next to the waveforms. FIGURE 3B shows Urect rectified voltage sample waveforms and the corresponding digital pulses when the dimmer is at medium setting, indicated by the average position of the dimmer cursor shown next to the waveforms. FIGURE 3C shows Urect rectified voltage sample waveforms and corresponding digital pulses when the dimmer is at its lowest setting, indicated by a lower position of the dimmer cursor shown next to the waveforms.
FIGURE 4 is a flow chart showing a process for detecting the phase angle of the dimmer, according to a representative embodiment. The process can be performed by firmware and / or software executed by the microcontroller 215 shown in FIGURE 2, or more generally by a processor or controller, e.g., the phase angle detector 110 shown in FIGURE 1, for example.
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In block S421 of FIGURE 4, the rising edge of a digital pulse of an input signal (eg, indicated by the rising edges of the background waveforms in Figures 3A-3C) is detected, for example, by the initial loading of the first capacitor C213. Sampling at digital input 218 of microcontroller 215, for example, starts at block S422. In the shown embodiment, the signal is digitally sampled for a predetermined time equal to or just below a main half cycle. Each time the signal is sampled, it is determined in block S423 whether the sample has a high level (eg, digital 1) or a low level (eg, digital 0). In the shown embodiment, a comparison is made in block S423 to determine if the sample is digital 1. When the sample is digital 1 (block S423: Yes), a counter is incremented in S424, and when the sample is not digital 1 (block S423: No), a small delay is inserted in block S425. The delay is inserted in such a way that the number of clock cycles (eg, of microcontroller 215) is equal regardless of whether the sample is determined to be digital 1 or digital 0.
In block S426, it is determined whether the entire main half cycle has been sampled. When the main half cycle is not complete (block S426: No), the process returns to block S422 to again sample the signal at digital input 218. When the main half cycle is complete (block S426: Yes), sampling stops and the Counter value accumulated in block S424 is identified as the current dimmer phase angle in block S427, and the counter is reset to zero. The counter value can be stored in a memory, examples of which are discussed above. Microcontroller 215 can then wait for the next rising edge to start sampling again.
For example, it can be assumed that the microcontroller
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215 take 255 samples during a main half cycle. When the dimming level or phase angle is adjusted by the cursor near the top of its range (eg, as shown in FIGURE 3A), the counter increments by about 255 in block S424 of FIGURE 4. When the level of dimming dimming is adjusted by the cursor near the bottom of its range (eg, as shown in FIGURE 3C), the counter will increase to only about 10 or 20 in block S424. When the dimer level is adjusted somewhere in the middle of its range (eg, as shown in FIGURE 3B), the counter will increase to about 128 in block S424. The counter value thus gives the microcontroller 215 an accurate indication of the level at which the dimmer has been set or the phase angle of the dimmer. In various embodiments, the phase angle of the dimmer can be calculated, for example, by the microcontroller 215, using a predetermined function of the counter value, where the function can vary to provide unique benefits for any given situation or meet design requirements specific to the various achievements, as would be apparent to a technician on the subject.
Thus, the phase angle of the dimmer can be detected electronically, using minimal passive components and a digital input structure from a microcontroller (or other processor or controller circuit). In one embodiment, the phase angle is detected using an AC coupling circuit, a microcontroller diode attached to the digital input structure and an algorithm (eg, consisting of firmware, software and / or hardware) executed to determine the dimmer adjustment level.
Additionally, the condition of the dimmer can be measured with minimum component count and having an advantage
24/56 of the digital input structure of a microcontroller.
The digital phase angle detection circuit and associated algorithm can be used in various situations where it is desired to know the phase angle of a phase cut dimmer. For example, electronic transformers that operate on load for a phase cut dimmer can use this circuit and method to determine the phase angle of the dimmer. When the dimmer phase angle is known, the dimmerization range and dimmer compatibility can be improved with respect to solid state luminaires (eg LEDs). Examples of such improvements include controlling the color temperature of a dimmer-adjusted lamp, determining the minimum charge that a dimmer can operate on site, determining when a dimmer behaves irregularly on site, increasing the maximum and minimum ranges of the light, and creating special dimming light for the cursor position curves.
The dimmer phase angle detection circuit, according to various achievements, can be performed on several Essentialwhite ™ and / or eW products manufactured by Philips Color Kinetics, including eW Blast PowerCore, eW Burst PowerCore, eW Cove MX PowerCore and eW PAR 38, and the like. In addition, it can be used as a building block for smart enhancements to make various products more dimmer favorable.
In various embodiments, a detection circuit, such as the representative detection circuit shown in FIGURE 2, can also be used to determine the presence or absence of a phase cut dimmer. Dimmer problems that occur regardless of the phase angle of the dimmer can be properly resolved by first determining whether the power converter is connected as a dimmer load. In such cases, a simple
25/56 binary determination of whether a dimmer is present and other information regarding whether the phase angle of the dimmer is not necessary, thus avoiding the detection of the phase angle, mentioned above, which is more computationally intense than a simple binary detection on the presence of a dimmer. Determining the presence of a dimmer may be sufficient to take some action to improve the compatibility of phase cut dimmers with LED drivers, for example. In addition, an algorithm for the presence of binary dimmer can be incorporated as part of larger algorithms, such as determining the main universal input voltage.
FIGURE 5 shows sample waveforms and corresponding digital pulses from a luminaire with and without a dimmer, according to a representative embodiment.
With reference to FIGURE 5, the upper set of waveforms shows the rectified main input voltage and the corresponding logic level digital pulses detected with a connected dimmer (indicated by the adjacent dimmer switch). The bottom set of waveforms shows the rectified main input voltage and the corresponding logic level digital pulses without a connected dimmer (indicated by an X on the adjacent dimmer switch). The hatched line 501 indicates a representative upper level boundary corresponding to the dimmer. The upper level limit can be determined by several means, including the empirical measurement of a dimmer on time at its highest setting, recovery of the on time from the manufacturer's database, or similar.
A phase cut dimmer does not allow the sine wave to pass through the full rectified main voltage, but it cuts a section of each waveform, even at its highest setting, as shown in the upper set of waveforms. In comparison, without a connected dimmer, the wave
26/56 sinusoidal of the complete rectified main voltage can pass, as shown in the lower set of waveforms. For example, if the digital pulse, as determined by the phase angle detector 210, does not extend beyond the upper level limit (as shown in the upper set of waveforms), the presence of a dimmer is determined. If the digital pulse extends beyond the upper level limit (as shown in the lower waveform set), it is determined that the dimmer is not present.
FIGURE 6 is a flow chart showing a process for determining whether a dimmer is present, according to a representative embodiment. The process can be carried out, for example, by firmware and / or software executed by the microcontroller 215 of FIGURE 2.
In block S621, the determined phase angle of the dimmer is recovered. For example, the phase angle of the dimmer as detected according to the algorithm shown in FIGURE 4 can be retrieved from memory (eg, where the information of the phase angle of the dimmer was stored in block S427). It is determined in block S622 whether the phase angle of the dimmer (eg digital pulse length) is less than the upper level limit. When the phase angle of the dimmer is not less than the upper level limit (block S622: No), the process returns to block Ξ621 and the determined phase angle of the dimmer is recovered again, so that the phase angle of the dimmer continues to be monitored. Also, in various embodiments, a dimmer detection marker can be adjusted at the bottom, indicating that there is no dimmer present, and / or the process can end. When the phase angle of the dimmer is determined to be lower than the upper level limit (block S622: Yes), the dimmer detection marker is set high in block Ξ623, for example, indicating the presence of a dimmer. Of course, in alternative realizations,
27/56 can be determined if the recovered phase angle is greater than (opposite to less than) the upper level limit, without abandoning the scope of the present teachings.
Thus, the presence or absence of a dimmer can be detected electronically, using minimal passive components and a digital input structure from a microcontroller (or other processor or processing circuit). In one embodiment, the dimmer detection is made using an alternating coupling circuit, a microcontroller diode fixed to the digital input structure and an algorithm (eg, consisting of firmware, software and / or hardware) executed for binary presence determination of the dimmer. As indicated above, electronic detection of whether a solid state lighting power converter (eg, LED) is connected as a load to a phase cut dimmer can be done using the same components as the representative embodiment shown in FIGURE 2 , for example, although a computationally less intense and time-insensitive algorithm can be used.
Detection circuit for the presence of the dimmer and associated algorithm can be used in various situations where it is desired to know whether an electronic transformer is connected as a load of a phase cut dimmer, for example. When the presence or absence of a dimmer has been determined, compatibility with dimmers with respect to solid state luminaires (eg LEDs) can be improved. Examples of these improvements include compensation for loss of front power due to a cut in the fully connected phase of a dimmer, increasing efficiency by cutting out all unnecessary functions if the dimmer is not present, and changing a leak load to help the minimum load requirement of the dimmer if the dimmer is present.
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The dimmer detection circuit, according to various achievements, can consist of several Essentialwhite ™ and / or eW products available from Philips Color Kinetics, including eW Blast PowerCore, eW Burst PowerCore, eW Cove MX PowerCore and eW PAR 3 8 and similar. In addition, it can be used as a building block for smart enhancements to various products to make them more dimmer friendly.
In various embodiments, the microcontroller 215's functionality may consist of one or more processing circuits, consisting of any combination of hardware, firmware or software architectures, and may include its own memories (eg, non-volatile memory) to store codes software / firmware executables that allow the performance of various functions. For example, functionality can be accomplished using ASICs, FPGAs, and the like.
Depositors also recognized and appreciated that, in addition to a circuit capable of detecting the dimmer phase angle of a solid state luminaire, and / or if a phase cut dimmer is present, it would be beneficial to provide a circuit that determines the voltage main input for providing the universal voltage input for a solid state luminaire when the dimmer level is set high enough to make this determination. Otherwise, a previously determined main input voltage, eg from memory, is recovered.
FIGURE 7 is a circuit diagram showing a representative lighting system for a solid state luminaire, according to various embodiments. Similar to the dimming control system 200 of FIGURE 2, the dimming control system 700 shown in FIGURE 7 includes a rectification circuit 705 connected to a dimmer (not
29/56 shown), a phase angle detection circuit for dimmer 710 (hatch box), a power converter 720, a waveform input sampling circuit 730 (hatch box) and LED load 74 0 Microcontroller 715 is included in both the phase angle detection circuit of dimmer 710 and the waveform input sampling circuit 730.
In the configuration shown, the rectifying circuit 705 includes four diodes D701-D704 connected between the rectified voltage node N2 and the earth. The rectified voltage node N2 receives the rectified voltage Urect (dimerized) being connected to earth by the input filter capacitor C715 connected in parallel to the rectifying circuit 705.
The phase angle detection circuit of the dimmer 710 includes a microcontroller 715, which has a digital output, such as the PWM output 719 connected to the control line 729. In various embodiments, the microcontroller 715 can be a PIC12F683, available from Microchip Technology, Inc., for example, although other types of microcontrollers or other processors can be included without departing from the scope of the present teachings, as discussed above with respect to microcontroller 215 in FIGURE 2. In the shown embodiment, the phase angle detection circuit 710 further includes a first and a second capacitor C713 and C714 and first and second resistors R711 and R712, which are configured and operate in substantially the same way as the first and second capacitors C213 and C214 and the first and second resistors R211 and R212 of FIGURE 2, and so the corresponding descriptions will not be repeated. Thus, a digital pulse of the logic level at the digital input 718 of the microcontroller 715 closely follows the movement of the cut Urect rectified voltage, coupled in alternating current to a digital input 718 of the microcontroller 715.
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In addition, the waveform input sampling circuit 730 also includes microcontroller 715, as well as a voltage divider that includes a third and fourth resistor R731 and R732, which provide a split version of the rectified Urect voltage. In the shown embodiment, the third resistor R7 31 is connected between the rectified voltage node N2 and the sampling node of the waveform N3, and the fourth resistor R732 is connected between the sampling node of the waveform N3 and the ground. In one embodiment, the third resistor R731 can have a value of about 1.5 megaohm and the fourth resistor R732 can have a value of about 15 kohm, for example. However, the respective values of the third and fourth resistors R731 and R732 may vary to provide exclusive benefits for any given situation or to comply with application-specific design requirements of the various achievements, as would be apparent to a person skilled in the art.
Waveform input sampling circuit 730 essentially provides a split version of the rectified input voltage Urect of rectification circuit 705, which allows microcontroller 715 to determine an accurate representation of the input waveforms via an analog input 717. The microcontroller 715 can use the waveforms to determine the main uncut input voltage, that is, the voltage at the input of the dimmer. As part of the phase angle detection circuit of dimmer 710, discussed above, microcontroller 715 also receives information regarding the phase angle (or dimer level) of the dimmer.
As discussed above, the power converter 720 operates on an open circuit or forward power, as shown in U.S. Patent No. 7,256,554 to Lys, for example, incorporated herein by reference. 0
31/56 microcontroller 715 can control the power setting of the power converter 720 using a power control signal output at the PWM output 719 via the control line 729. In various embodiments, the power converter 720 can be an L6562 , available from ST Microelectronics, for example, although other types of microcontrollers, power converters and other processors can be included without departing from the scope of the present teachings.
Generally, a software and / or firmware algorithm executed by the 715 microcontroller has the advantage that at large dimmer phase angles (less cut waveforms), as shown in FIGURE 8A, the main input voltage can be determined with greater precision, which can then be used to more precisely control the power setting of the 720 power converter. However, at a smaller phase angle of the dimmer (more heavily cut waveforms), as shown in FIGURE 8B, the voltage determination main input becomes computationally intense and requires a high quality microcontroller, or other processor or controller, because there are so few waveforms available for measurement. Therefore, according to several realizations, an example that is discussed below with reference to FIGURE 9, instead of performing this intensive analysis at smaller dimmer phase angles, the power control signal is adjusted based on a previously determined value and stored from the main input voltage, eg calculated when the dimmer was at a large dimmer phase angle, or calculated using a more flexible (but less accurate) classification algorithm, an example of which is discussed below with reference to FIGURE 13. This avoids having to incorporate a high quality microcontroller and / or relatively long processing times.
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The dimmer phase angle above at which more precise determination of the input waveform and the main input voltage can occur is referred to as the limit of determination. In various embodiments, the limit of determination is a predetermined phase angle of the dimmer at which microcontroller 715 can gather enough samples to perform an accurate determination of the main input voltage. The determination limit can therefore change depending on several factors, such as the speed of the 715 microcontroller and the effectiveness of the algorithm used to determine the main input voltage of the cut waveform, for example. The cost of microcontroller 715 and the precision of the power signal provided by microcontroller 715 to the power converter 720 via control line 729 can therefore be compensated.
FIGURE 8A shows sample waveforms of a dimmer having a phase angle above the determination limit, according to a representative embodiment, so that an accurate measurement of the input voltage can be made by the microcontroller 715, e.g. , via the waveform input sampling circuit 73 0 and the analog input 717 shown in FIGURE 7, using the peak and valley detection algorithms discussed below, eg with reference to Figures 14 and 15, respectively . FIGURE 8B shows sample waveforms of a dimmer having a phase angle below the limit of determination, according to a representative embodiment, so that a previously determined input voltage, eg, calculated when the phase angle of dimmer was above the determination limit, and using the last best power adjustment correspondent to adjust the power of the power converter.
Alternatively, when a
33/56 previously determined input voltage, the input voltage and the corresponding power adjustment can be determined using an alternative, and somewhat less accurate, classification method, an example of which is discussed below with reference to FIGURE 13.
FIGURE 9 is a flowchart showing a process for determining the main input voltage and corresponding power adjustment based on the detected phase angle of the dimmer, according to a representative embodiment.
With reference to FIGURE 9, in the shown embodiment, it is initially determined in block S910 whether the process is being carried out, according to a first power activation of the solid state luminaire, which occurs the first time that energy is applied to the status luminaire. solid. When it is not the first drive (block 3910: No), a previously determined main input voltage value is retrieved from memory, like an EEPROM, in block 3920. Alternatively, the memory can include any type of volatile or non-volatile memory. computer, such as RAM, ROM, PROM, EPROM, USE drive, floppy disks, compact discs, optical discs, magnetic tape and the like. The previously determined main input voltage value correlates with an associated power setting of the power converter 720 using a pre-populated look-up table, for example, or other means of association. The associated power setting is applied to the power converter 720 via the output of the power control signal from the 715 microcontroller, so that the solid state luminaire operates normally while the main current input voltage is being determined.
The phase angle of the dimmer is detected in the block
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S921. The phase angle of the dimmer can be obtained, for example, according to the process of detecting the phase angle of the dimmer shown in FIGURE 4, discussed above. In block S922, it is determined whether the phase angle of the dimmer is below the determination limit. When the phase angle of the dimmer is below the determination limit (block S922:
Yes), the previously determined main input voltage and the associated power setting, called the last best power setting, are used as the current power setting in block S924. In one embodiment, the last best power setting is the setting of power determined based on the main input voltage recovered in the S920 block, which simply does not change in the S924 block when the dimmer phase angle is below the determination limit.
When the phase angle of the dimmer is not below the determination limit (block S922: No), a new main input voltage and the corresponding power adjustment in block S926 are determined. In one embodiment, the 730 waveform input sampling circuit and the 715 microcontroller waveform analog input splitter are used with the peak and valley detection algorithms, eg discussed below with reference to the Figures 14 and 15, to determine the main precision input voltage and power setting. For example, microcontroller 715 can be constituted substantially as controller 1020 in FIGURE 10, discussed below, and thus receive digital values of DC voltage signals from an analog to digital converter (such as A / D 1022 in FIGURE 10), corresponding to split version of the rectified Urect voltage of the voltage divider that includes a third and fourth resistor R731 and R732.
Because the phase angle of the dimmer is known to be above the limit of determination, the voltage
35/56 main input can be continuously determined, as opposed to limiting the determination to one of the multiple predetermined input voltages and power settings (ie rating), as discussed below with reference to FIGURE 13. In other words , the peak and slope detection methods of Figures 14 and 15 can be used to specifically determine the value of the main input voltage and thus to determine a precise power adjustment. As previously discussed, the determined value of the main input voltage can be correlated with a power adjustment using a pre-filled query table, for example, or other means of association.
Referring again to block S910, when the first drive is made (block S910: Yes), there is no power adjustment of the main voltage previously determined from the input to be loaded from memory. Thus, the process proceeds to block S911, where the phase angle of the dimmer is detected, as discussed above with respect to block S921. In block S912, it is determined whether the phase angle of the dimmer is below the determination limit. When the phase angle of the dimmer is not below the determination limit (block S912: No), a new main input voltage and the corresponding power adjustment in block S926 are determined, as discussed above.
However, when the dimmer setting is below the determination limit (block S912: Yes), because there is no previously determined main input voltage to be recovered, the classification detection algorithm is constituted in block S914 to place the main voltage of input into one of multiple classifications, for example, 120V, 230V or 277V. An example of the classification detection algorithm is discussed below
36/56 with reference to FIGURE 13. The power setting corresponding to the rated voltage is then used by the power converter 720 until it is determined that the phase angle of the dimmer has moved above the determination limit, e.g. , according to the subsequent performances of the method in FIGURE 9, in which case a more accurate determination of the waveform, and thus of the main input voltage and the power adjustment, can be done without classification. In various embodiments, the S914 block may include an algorithm, other than the classification one, that requires less cut waveforms than the input voltage determination algorithm of the S926 block to estimate the input voltage (thus operating at smaller angles of dimmers phase), without abandoning the scope of the present teachings.
The phase angle and detection circuit determination limit and the associated algorithm can be used in various situations where it is desired to establish the power setting of a power converter. According to various realizations, the charging power of the LED, for example, can be adjusted over a continuous range of main input voltages using a relatively low power / low cost processor when the dimmer phase angle is above the limit of determination. For example, the actual power for the LED load can be determined by the RMS input voltage and the signal that the microcontroller sends to the power converter.
A rating process adjusts the power control signal sent to the power converter, eg by a microcontroller, to a limited number of possible values (eg, three values in response to the main input voltages 120V, 230V or 277V). Since the actual power of the LEDs is determined by both the RMS input voltage and the microcontroller signal, when the
37/56 RMS input voltage is, for example, 17 9V or 2 08V, the exact power may not be sent to the LEDs. For example, a rating setting may not determine the difference between 100V (commonly used in Japan) and 120V (commonly used in North America). As a result, when operated at 100V, the rating implementation can set the microcontroller power control signal to a value suitable for 120V, yet the RMS input voltage will be less and so the power sent to the LEDs and the luminous power will be incorrect. Similarly, in the European Union, the main input voltages are 220V or 24V, which can cause the same problem. The use of a digital phase angle detection circuit, for example, in FIGURE 2, allows the exact main input voltage (and the corresponding power setting) to be determined, at least in those situations where the dimmer setting high enough.
Also, as discussed above, it is difficult to determine the main input voltage of a heavily cut sine wave. Thus, when the phase angle of the dimmer is very low (eg, as shown in FIGURE 8B), it is expensive and computationally intense to determine the entire sine wave of which the cut section is part. According to various realizations, this can be avoided by determining the main input voltage only when the dimmer is above a determination limit where an exact determination can be made, eg without having to substantially increase the processing power or the load of the 715 microcontroller.
FIGURE 10 is a block diagram showing a lighting system, including a solid state luminaire and an input voltage controller, according to a representative embodiment. With reference to FIGURE 10, the
38/56 input voltage controller 1010 includes a voltage divider 1015, an analog to digital (A / D) converter 1022, a controller 1020 and a power factor mode correction controller (PFC) 1030.
voltage divider 1015 receives rectified voltage from a power source.
Generally, the rectified voltage is a voltage signal from the alternating line or the main input having a voltage value, e.g. , between about 9 0VAC and about 277VAC, and a corresponding waveform. The main input voltage signal is used to drive the solid state luminaire 1040. The voltage divider 1015 provides a signal corresponding to a split version of the rectified input main voltage signal. The voltage signal is sent to the A / D converter 1022 as an analog signal for the input voltage.
In the shown embodiment, the voltage divider 1015 includes a first and a second resistor 1011 and 1012 connected in series between the rectified input voltage source and the Nil node, which is connected to an input of the controller 1020. The voltage divider 1015 it also includes a third resistor 1013 connected between the Nil node and the earth. In one embodiment, the first and second resistors 1011 and 1012 individually have a resistance of about 750 kQ, and the third resistor 113 has a resistance of about 13 kQ. It is understood that, in other embodiments, the resistance values from the first to the third resistors 1011-1013 and / or the configuration of the voltage divider 1015 may vary to provide unique benefits for any particular situation or to meet specific design requirements of the application of the various achievements, as will be apparent to the technician in the subject.
A / D converter 1022 receives the analog signal from
39/56 input voltage of voltage divider 1015, converts the analog input voltage signal to digital values indicating the waveform of the rectified main input voltage. The controller 1020 receives the digital values from the A / D converter 1022 and determines the voltage level of the main input voltage based on the digital values. The controller 1020 sets a control signal based on the determined voltage level of the main input voltage, and sends the control signal to the PFC controller 103 0 to control the solid state luminaire 1040. For example, based on the control, the PFC controller 10 3 0 sends a power modulation control signal to operate the solid state luminaire 1040 in a continuous state of 3 0W for any detected value of the main input voltage (eg 120VAC, 230VAC or 277VAC ), as discussed below.
The 1020 controller can be composed of any combination of hardware, firmware or software architectures, as discussed above, without departing from the scope of the present teachings. Also, the 1020 controller can include its own memory (eg, non-volatile memory) for storing executable software / firmware codes that allow the various functions of the 1010 voltage controller to be performed. For example, in various embodiments, the 1020 controller it may consist of a microprocessor, ASIC, FPGA, microcontroller, such as a PIC12F683 microcontroller available from Microchip Technology, Inc. or similar. Likewise, the PFC 1030 controller can be composed of any combination of hardware, firmware or software architectures, without abandoning the scope of the present teachings. For example, in various embodiments, the PFC 1030 controller can be constituted as a microprocessor, ASIC, FPGA, microcontroller, as a PFC L6562 controller, available from ST Microelectronics, or similar. Furthermore, although
40/56 shown separately, it is understood that the A / D converter 1022 and / or □ PFC controller 1030, and associated functionalities, can be incorporated into the controller 1020 in various embodiments. In addition, in various embodiments, controller 1020 and PFC controller 103 0 may consist of microcontroller 715 and power controller 720 of FIGURE 7, for example, without departing from the scope of the present teachings.
FIGURE 11 is a block diagram of controller 1020, according to a representative embodiment. With reference to FIGURE 11, controller 1020 includes a processor 1024, read-only memory (ROM) 1026, random access memory (RAM) 1027 and PWM signal generator 1028.
As discussed above, the A / D converter 1022 receives the input signal from the voltage divider 1015, and converts the input signal to digital values, indicating the waveform of the rectified main input voltage. The digital values are received by the 1024 processor for processing, and can also be saved in ROM 1026 and / or RAM 1027, eg. via bus 1021. Processor 1024 may include its own memory (eg, non-volatile memory) for storing executable software / firmware codes that enable the various functions of the 1010 voltage controller to be performed. Alternatively, the executable code may be stored in indicated memory locations within ROM 1026 and / or RAM 1027. ROM 1026 can include any number, type and combination of tangible computer read storage media, such as PROM, EPROM, EEPROM, and the like. In addition, ROM 1026 and / or RAM 1027 can store statistical data and results from previous calculations of main input voltage by the 1024 processor, for example.
PWM signal generator 1028 generates and sends a signal
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PWM as a control signal, in response to instructions or control signals from the 1024 processor. More particularly, in the shown embodiment, the PWM signal generator 1028 varies the pulse width of the PWM control signals depending on the value of the determined input main voltage by the 1024 processor. For example, the PWM signal generator 1028 can generate PWM control signals with shorter pulse widths in response to higher values of the main input voltage. The PWM control signal is sent from controller 1020 to PFC controller 1030, which controls the power modulation of the solid state luminaire 140 according to the pulse widths of the PWM control signal. For example, the PFC 1030 controller can be configured to increase the current for the solid state luminaire 1040 in response to greater pulse widths, thus maintaining a constant power for lower voltage values (eg 120VAC). Likewise, the PFC 1030 controller can be configured to reduce the current for the 1040 solid state luminaire in response to smaller pulse widths, while maintaining constant power for higher voltage values (eg 277VAC).
For example, in one embodiment, the PFC 1030 controller has a dedicated current adjustment pin on its device. By adjusting a voltage reference on the current adjustment pin, the PFC 1030 controller will deliver an amount of power to the 1040 solid state luminaire that relates to the voltage reference seen on the current adjustment pin. The power of the PWM control signal from the 1020 controller (with varying pulse width, depending on the input voltage waveform) goes through the filter circuit (not shown) on the PFC 1030 controller and effectively changes the voltage reference on the control pin. current adjustment of the PFC 1030 controller. This allows for a change in power
42/56 total that travels the LEDs in a set of LEDs 1045 of the solid state luminaire 1040. Of course, other types of signals and control methods to control the solid state luminaire 1040 can be incorporated into the scope of the present teachings.
Referring again to FIGURE 10, the solid state luminaire 1040 can be an Essentialwhite ™ luminaire, available from Philips Color Kinetics, for example. The solid state luminaire 1040 includes a switch 1041 and a light source or light source, as representative set LED 1045. The switch 1041 turns the power on and off for the LED set 1045 in response to the power modulation control signal received from the PFC 1030 controller, which concurrently changes the continuous state current. For example, the amount of time on can determine the amount of current that travels through the LEDs of the 1045 LED array. The timing or power switching cycle for the 1045 LED array thus adjusts the various values of the main input voltage. For example, a higher main input voltage (eg 277VAC) requires shorter on intervals (resulting in less current) to supply continuous power (eg, 30W) to the 1045 LED array than a lower main input voltage. (eg 120VAC).
FIGURE 12 is a flow chart showing a process for controlling the power of a solid state luminaire, according to a representative embodiment. The various steps and / or operations shown in FIGURE 12 can consist of an A / D converter 1022 and controller 1020, for example, discussed above with reference to Figures 10 and 11.
In block S1210, a rectified AC line voltage or input main voltage signal is received
43/56 for the activation of the solid state luminaire. The magnitude or value of the main input voltage signal is not known, and can be any of the available main input voltages, such as 120VAC, 230VAC or 277VAC. In block S1212, the input main voltage signal is converted into a downward divided signal, eg by the voltage divider 1015, which provides a downward divided signal corresponding to a waveform of the input main voltage signal . The split-down signal is converted from analog to digital, eg, by the A / D converter 1022, in block S1214 to provide digital values that represent the waveform of the input main voltage signal.
In S1216 operation, the magnitude or value of the main input voltage signal is determined, for example, by controller 1020 and / or processor 1024, using the digital values, described in greater detail with reference to Figures 13-15, below . Generally, a peak detection algorithm is performed to determine whether the main input voltage has a high or intermediate value {e.g. , 277VAC or 220-240VAC). However, the peak detection algorithm individually may not be able to detect the main input voltage value, for example, when the main input voltage has a lower value (eg 120VAC) or when the main input voltage signal has an intermediate value (eg 230VAC) that has been dimmed. When the peak detection algorithm cannot detect the value of the main input voltage, a slope detection algorithm is performed to determine if the slope of the rising edge of the waveform of the main input voltage signal corresponds to the low value or the intermediate value.
After the value of the main input voltage is determined, a control signal is generated and sent, by
44/56 ex. , to the PFC controller 1030, based on the value determined in block S1218. Based on the control signal, the power modulation of the solid state luminaire is adjusted according to the main input voltage value.
FIGURE 13 is a flow chart showing a process for determining the value of the main input voltage signal, according to a representative embodiment. More particularly, FIGURE 13 shows a representative embodiment in which the value of the main input voltage (or alternating line voltage) is associated with one of the multiple predetermined voltage values (e.g., low, intermediate or high). The process can be called classificatory since the main input voltage is placed in a reservoir that corresponds to one of the predetermined voltage values.
In various embodiments, the exact value of the main input voltage can be determined, eg based on peak and valley detection processes shown in blocks S1320 and S135Q of FIGURE 13, whenever the cut sine wave produced by a dimmer phase shear is sufficient to allow this determination. For example, as discussed above with reference to Figures 7-9, when the phase angle of the dimmer is above a determination limit (eg, as a master in FIGURE 8A), the exact value of the main input voltage can be calculated using relatively small processing power.
With reference to FIGURE 13, the process is first initiated indicated, for example, by blocks S1312 and S1314. In one embodiment, the initialization is done only when the solid state luminaire is energized, although the initialization may be omitted entirely or at other times within the process for determining the value of the main input voltage in realizations
45/56 alternatives, without abandoning the scope of the present teachings. When available, the previously determined main input voltage value is retrieved from memory in block S1312, and the control signal, eg. , produced by controller 1020, is initially set based on the value of the main input voltage previously determined in block 81314. If the control signal is a PWM control signal, for example, the PWM pulse width or the duty cycle is initially set according to the previously determined main input voltage value. For example, the value of the main input voltage can be determined and saved, for example, in ROM 1026, each time the solid-state luminaire is switched on. Thus, the solid state luminaire is operated at a previously determined value of the main input voltage, while the present value of the main input voltage is being determined. This avoids flickering or other adverse effects during the determination process.
In operation S1320, a peak detection algorithm is performed to detect the peaks and frequency of the main input voltage signal, based on the digital values, eg provided by the A / D converter 122. The algorithm for the peak operating detection S1320 is discussed in detail with reference to FIGURE 14, which is a flow chart showing a process for determining signal peaks and signal frequency of the main input voltage, in accordance with a representative embodiment.
With reference to FIGURE 14, the digital values of the DC voltage signals (eg from block S1214 of FIGURE 12) are read for a predetermined number of cycles (eg, 20 cycles) or for a predetermined period of time ( eg 150mS) to identify and store the maximum digital values corresponding to the waveform peaks
46/56 of the main input voltage signal, and / or to identify the frequency of the main input voltage signal. For example, processor 1024 can sample a number of digital values from the 1022 A / D converter's DC voltage signal. To identify the maximum digital values, a digital value from the down-divided signal, corresponding to a split version of the main rectified voltage input, is read in block S1421 and compared to a maximum value in block S1422. The maximum value can be a predetermined limit value or a stored digital value that has been previously determined to be the maximum value among the previously read digital values.
When the digital value read is greater than the maximum value (block S1422: Yes), the digital value read is saved as the new maximum value in block S1423, to be used in comparisons with the digital values subsequently read. When the digital value read is not greater than the maximum value (block 31422: No), block S1423 is ignored. It is determined in block S1424 whether other cycles (or times) remain for reading the digital values. For example, the number of cycles or elapsed time can be compared to a predetermined limit or a predetermined period of time, respectively, for reading digital values. When there are additional cycles or times (block S1424: Yes), blocks S1421 to S1423 are repeated. When there are no more cycles or times for reading the digital values (block S1424: No), the maximum current value between the sampled digital values is considered the peak value of the waveform.
The waveform frequency of the main input voltage is calculated in block 31425, eg by comparing the timing between crossings at zero or between adjacent peak values. For example, it is determined in the block
47/56
S1425 if the main input voltage is 50Hz or 60Hz, which is typically dictated by the geographic location of the solid state luminaire installation. The frequency of the waveform is determined, as it directly influences the inclination of the waveform, which is calculated in operation S1350 of FIGURE 13, discussed below. In one embodiment, the frequency of the waveform can be determined by sampling a point on the waves of the waveform (eg, peaks or wave start points) over a cycle period and calculating the time period between waves adjacent.
After determining the frequency in block S1425 of FIGURE 14, the process returns to FIGURE 13. In blocks S1332-S1335 of FIGURE 13, it is determined whether the value of the main input voltage signal can be determined without having to determine the slope corresponding waveform. In particular, in block S1332, the peak value of the waveform is compared to a first predetermined limit value to determine whether the value of the main input voltage signal is a maximum voltage value (e.g., 277VAC). When the peak value is greater than the first limit value (block S1332: Yes), the value of the main input voltage signal is determined to be the maximum voltage value in block S1333.
When the peak value is not greater than the first limit value (block S1332: No), the process proceeds to block S1334, where the peak value of the waveform is compared to a second predetermined limit value to determine whether the value of the main input voltage signal is an intermediate voltage value (eg 230VAC) or a range of possible intermediate voltage values (eg 2 2OVCA-24 0VAC). When the peak value is greater than the second limit value (block S1334: Yes), the value of the main input voltage signal is determined to be the value
48/56 voltage intermediate (or the range of possible intermediate voltage values) in block S1335.
When the peak value is not greater than the second limit value (block S1334: No), the process determines the value of the main input voltage signal based on the slope of the waveform. That is, when the peak value is not greater than the second limit value, the main input voltage signal can either be a low voltage value (eg 120VAC) or a dimmed intermediate voltage value (eg. , 230VAC), conditions that are not otherwise distinguishable based solely on the determination of the peak value.
For example, Figures 16A and 16B are sample waveform traces of a 120VAC line voltage signal and a 230VAC dimmerized line voltage signal, respectively. The comparison of Figures 16A and 16B shows that the frequency and peaks of the corresponding waveforms are substantially the same, but that the slopes of the waveforms are different. In particular, the slopes of the waveform in FIGURE 16B are generally greater than the slopes of the waveform in FIGURE 16A. Therefore, when calculating the slope (eg, in operation S1350 in FIGURE 13), a determination can be made as to whether the main input voltage signal is 120VAC or 230VAC, regardless of the dimming. Of course, a 120VAC dimmerized line voltage signal (not shown), which may have a waveform with an inclination similar to the 230VAC dimmerized line voltage signal in FIGURE 16B, would still be distinguishable based on smaller peaks. Therefore, in one embodiment, another peak comparison can be made (not shown) if the slope calculations are not conclusive.
Thus, when it is determined in block S1334 that the
49/56 peak value is not greater than the second limit value (block S1334: No), the process performs a slope detection algorithm, indicated by the S1350 operation, to determine the slope corresponding to the rising edges of the signal waveform main input voltage based on digital values, eg , supplied by the A / D converter 1022. The slope detection algorithm of the S1350 operation is discussed in detail with reference to FIGURE 15, which is a flowchart showing a process for determining the slopes of the main voltage signal waveform. entry, according to a representative realization.
With reference to FIGURE 15, the reference criteria are selected to determine the slope in block S1451. The selection of reference criteria is based on the frequency of the main input voltage signal, which was previously determined, for example, in operation S1320 and in FIGURE 14, discussed above. The reference criteria associate a slope or range of slopes at each possible frequency corresponding to the value of the low dimerized voltage and the intermediate value of the dimmed voltage, so that the calculated slope can be compared to each one. For example, FIGURE 17 is a graph showing the sample slopes on which the reference criteria can be based. Slope 1710 corresponds to a rising edge of the waveform in a 230VAC dimmerized line voltage signal and slope 1720 corresponds to a rising edge of the waveform in a 120VAC dimmed line voltage signal. As discussed above, the higher value of the main input voltage signal (slope 1710) is more inclined.
Digital values corresponding to the split version of the rectified input main voltage are read (eg in A / D converter 1022) in block S1452. In one embodiment, the
50/56 waveform of the main input voltage signal must be sampled (using the digital values read) in an approximate time period of 2.5mS, for example, because this is the minimum amount of the waveform available when dimmers ELVs are dimerized at their lowest levels. If sampling occurs in more than about 2.5ms, there may not be an alternating current signal, as it may have been cut by the dimmer. Based on the digital values read, the rising edge of the main input voltage signal waveform in block S1453 is identified. For example, by monitoring digital values over a period of time, the rising edge can be immediately identified with the identification of digital values that start to increase after a series of decreasing or unchanged digital values.
When the rising edge of the waveform is identified, the slope of the rising edge is calculated in block S1454 using multiple digital values that represent at least part of the rising edge. For example, a predetermined number and / or sampling of digital values can be collected or digital values can be collected over a predetermined period of time. In one embodiment, the slope of the rising edge is calculated by comparing each of the selected digital values corresponding to the rising edge with the previous digital value. For example, using ten digital values representative of the rising edge of the waveform, an increase of about 50 counts (see 1710 of FIGURE 17) between adjacent digital values would indicate a line voltage of 230VAC, while an increase of about 25 counts (see curve 1720 of FIGURE 17) between adjacent digital values would indicate a line voltage of 120VAC.
In block S1455, the calculated slope is compared with the reference criteria selected in block S1451,
51/56 that depend on the frequency of the main input voltage signal. In the shown embodiment, the calculated slope is only compared with the reference criteria corresponding to a low voltage value (eg 120VAC) for the purposes of description. However, it is understood that, in various embodiments, the calculated slope can be compared together or individually to the reference criteria for low voltage and intermediate voltage (eg 230VAC), without abandoning the scope of the present teachings. When the comparison indicates that the calculated slope corresponds to the low voltage value (block S1455: Yes), a low voltage counter is increased in block S1456, and when the comparison indicates that the calculated slope does not correspond to the low voltage value {block S1455: No), an intermediate voltage value counter is increased in block S1457.
In block S1458, it is determined whether other sampling cycles remain. For example, a predetermined number of slopes (eg 60) can be calculated for corresponding sets of digital values, or the slope calculations can be repeated and collected over a predetermined period of time (eg 450mS). When other sampling cycles remain (block S1458: Yes), the process returns to the beginning, and blocks S1451 to S1458 are repeated. When no other sampling cycles remain (block S1458: No), the process proceeds to block S1459, where the value of the main input voltage signal is determined. For example, at least one of the counter values can be compared to the predetermined limit to determine whether the slopes individually or collectively indicate that the value of the main input voltage signal is the intermediate voltage value or the low voltage value.
In one realization, only the cash value counter
52/56 intermediate voltage is compared to a predetermined limit, selected to indicate whether the value of the main input voltage signal is the intermediate voltage value, although several achievements may compare one or both counters, or constitute another identification technique comparable. In the example where the predetermined number of slopes being calculated is 60, the predetermined limit for the intermediate voltage can be 20, in which case the process determines that the value of the main input voltage signal is the intermediate voltage only when the number of calculated slopes indicating the intermediate voltage value exceeds 20.
After determining the voltage value in block S1459 of FIGURE 15, the process returns to FIGURE 13. Depending on the result, the value of the main input voltage signal is determined to be the lowest voltage value in block S1360 or the intermediate voltage value in block S1361. In the S1370 block, the determined voltage value (from one of the S1333, S1335, S1360 or S1361 blocks) is compared to the previously stored voltage value, initially retrieved from memory in the S1312 block. When the determined voltage value is the same as the previously saved voltage value (block S1370: Yes), the process ends. In this case, the control signal (eg, output from controller 1020) remains unchanged from the setting provided by the initialization process. That is, the control signal remains based on the previously stored voltage value. When the determined voltage value is not the same as the previously saved voltage value (block S1370: No), the new voltage value of the main input voltage signal is saved (eg, in ROM 1026) and applied to change the control signal. In response, the PFC 1030 controller, which receives the control signal from the
53/56 controller 1020, changes the power modulation control signal provided to the solid state luminaire 1040 to adjust the changed voltage value.
Although multiple embodiments of the invention have been described and illustrated herein, those skilled in the art will readily see a variety of other means and / or structures for carrying out the function and / or obtaining the results and / or one or more of the described advantages herein, and each of these variations and / or modifications must be within the scope of the embodiments of the invention described herein. For example, FIGURE 13 addresses a representative embodiment where the main input voltage is determined to be one of three values according to a voltage rating process, a high voltage value, an intermediate voltage value or a low voltage value, which can correspond to 277VAC, 230VAC and 120VAC respectively. However, several other achievements can be configured to determine different voltage values or voltage value ranges (eg, different from 277VAC, 230VAC and 120VAC) and / or to determine a different number of voltage values (eg, more or less than three) of main input tensions, without abandoning the scope of the present teachings.
Those skilled in the art will readily see that all parameters, dimensions, materials and configurations described herein are exemplary only and that the actual parameters, dimensions, materials and / or configurations will depend on the specific application or applications where the teachings of the invention are being used. . Those skilled in the art will see or be able to certify using no more than routine experimentation, many equivalent to the specific embodiments of the invention described herein. Therefore, it should be understood that the above achievements are presented
54/56 only as examples and that, within the scope of the appended claims and their equivalents, the realizations of the invention can be practiced in ways other than those specifically described and claimed. The realizations of the invention of the present disclosure are directed to each individual characteristic, system, article, material, kit, and / or method described herein. In addition, any combination of any two or more of these characteristics, systems, articles, materials, kits, and / or methods, if these 10 characteristics, systems, articles, materials, kits, and / or methods do not. are mutually inconsistent, they will be included in the scope of the invention of the present disclosure.
All definitions, as defined and used herein, must be understood to control dictionary definitions, definitions in documents incorporated by reference, and / or common meanings of defined terms.
The indefinite articles one and one, as used herein in the specification and the claims, unless clearly indicated to the contrary, are to be understood as 20 meaning at least one.
The phrase e / or, as used herein in the specification and in the claims, should be understood as meaning each or both of the elements thus together, that is, elements that are present together in some cases and present not together in other cases.
Multiple elements listed with and / or must be understood in the same way, that is, one or more of the elements thus together. Other elements may optionally be present in addition to the elements specifically identified by clause e / or, whether or not they are related to the elements specifically identified. Thus, as a non-limiting example, the reference to A and / or B, when used in conjunction with open-ended language as
55/56 comprising may, in one embodiment, refer to A only (optionally including elements other than B), in another embodiment, B ONLY (optionally including elements other than A); in yet another embodiment, both A and B (optionally including other elements); etc.
As used herein in the specification and in the claims, it should either be understood to have the same meaning as and / or as defined above. For example, when separating items in a list, either or or and / or should be interpreted as being inclusive, that is, the inclusion of at least one, but also including more than one, of a number or list of elements and, optionally , other items not listed. Only terms clearly indicated to the contrary, such as only one of or exactly one of, or, when used in the claims, consisting of, refer to the inclusion of exactly one element of a number or list of elements. In general, the term or as used herein should only be interpreted as indicating exclusive alternatives (that is, one or the other, but not both) when preceded by terms of exclusivity, such as one of only one of or exactly one of. Essentially consisting of when used in the claims, it will have its common meaning as used in the field of patent law.
As used herein in the specification and in the claims, the phrase at least one, in reference to a list of one or more elements, is to be understood as meaning at least one element selected from any one or more of the elements in the list of elements, but not necessarily including at least one of each and all elements specifically mentioned in the list of elements and not excluding any combinations of elements in the list of elements. This definition also allows the elements to optionally be present, in addition to the elements
56/56 specifically identified in the list of elements to which the phrase at least one refers, whether or not they are related to the elements specifically identified. Thus, as a non-limiting example, at least one from A and B (or, equivalently, at least one from A or B, or, equivalently, at least one from A and / or B) can refer, in a carrying out at least one, optionally including more than one, A, without B present (and optionally including elements other than B); in another embodiment, at least one, optionally including more than one, B, without A present (and optionally including elements other than A); in yet another embodiment, at least one, optionally including more than one, A, and at least one, optionally including more than one, B (and optionally including other elements); etc.
It should also be understood that, unless clearly indicated to the contrary, in any of the methods claimed herein that include more than one step or act, the order of the steps or acts of the method is not necessarily limited to the order in which the steps or the acts of the method are mentioned.
All reference numerals or other characters that appear in parentheses in the claims are provided for convenience only and are not intended to limit the claims in any way.

权利要求:
Claims (9)
[1]
1. DEVICE FOR THE DETECTION OF A DIMMER PHASE ANGLE ESTABLISHED BY THE OPERATION OF A DIMMER FOR A LIGHTING LOAD IN SOLID STATE, The device comprising:
a processor (215) comprising a digital input (218);
a first diode (D211) connected between the digital input and a voltage source (Vdc);
a second diode (D212) connected between the digital input (218) and the ground, a first capacitor (C213) connected between the digital input (218) and a detection node (Nl), · a second capacitor (C214) connected between the detection node (Nl) and the ground; and a resistor (R212, R212) connected between the detection node and a rectified voltage node (N2), which receives a rectified voltage from the dimmer, where the first capacitor (C213) is configured to couple the rectified voltage in alternating current. at the detection node at the digital input, and the processor (215) is configured to sample the digital pulses at the digital input based on the rectified voltage and identify the dimmer phase angle based on the sampled digital pulse lengths.
[2]
DEVICE, according to claim 1, characterized in that the first capacitor is charged by the resistor on a rising edge of a waveform of the rectified voltage signal.
[3]
3. DEVICE, according to claim 2, characterized in that the first diode is fixed on a pin of the digital input in a diode drop above the voltage source when the first capacitor is charged, providing a
2/3 digital pulse having a length corresponding to the signal waveform.
[4]
4. DEVICE, according to claim 3, characterized in that the first capacitor discharges through the second capacitor on a falling edge of the signal waveform.
[5]
5. DEVICE, according to claim 4, characterized in that the second diode is fixed on a pin of the digital input of a diode drop below the ground when the first capacitor is discharged.
[6]
6. DEVICE, according to claim 3, characterized in that the processor additionally comprises a counter that increments a counter value while the first capacitor is charged.
[7]
7. DEVICE, according to claim 6, characterized in that the processor determines the length of the digital pulse based on the value of the counter.
[8]
8. DEVICE, according to claim 1, characterized in that the processor generates a digital control signal that corresponds to the identified phase angle and sends the digital control signal to a power converter, which sends a continuous voltage to the load of solid state lighting corresponding to the phase angle of the dimmer based on the digital control signal.
[9]
9. METHOD FOR THE DETECTION OF A DIMMER PHASE ANGLE ESTABLISHED BY THE OPERATION OF A DIMMER FOR A LU2 LED (LED), the method comprising:
receiving a digital input signal corresponding to a dimmerized rectified voltage received from the dimmer by means of an AC coupling circuit, the dimerized rectified voltage having the signal waveform;
detect a rising edge of a pulse from a digital input signal corresponding to a rising edge
3/3 of the signal waveform;
sample the pulse periodically to determine a pulse length; and determine the phase angle of the dimmer based on the
5 wrist length.

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同族专利:

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公开号 | 公开日

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KR101733399B1|2017-07-21|

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CA2781235A1|2011-05-26|

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EP2502465B1|2014-02-26|

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TW201119501A|2011-06-01|

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JP2013511803A|2013-04-04|

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EP2502465A1|2012-09-26|

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CA2781235C|2017-12-05|

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法律状态:
2020-05-12| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-05-19| B25D| Requested change of name of applicant approved|Owner name: KONINKLIJKE PHILIPS N.V. (NL) |

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2020-05-26| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2020-06-09| B25G| Requested change of headquarter approved|Owner name: KONINKLIJKE PHILIPS N.V. (NL) |

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2020-06-30| B25A| Requested transfer of rights approved|Owner name: PHILIPS LIGHTING HOLDING B.V. (NL) |

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2020-09-15| B11B| Dismissal acc. art. 36, par 1 of ipl - no reply within 90 days to fullfil the necessary requirements|

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2021-10-13| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

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申请号 | 申请日 | 专利标题

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US26277009P| true| 2009-11-19|2009-11-19|

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US61/262,770|2009-11-19|

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US28558009P| true| 2009-12-11|2009-12-11|

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US61/285,580|2009-12-11|

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PCT/IB2010/051594|WO2011061633A1|2009-11-19|2010-04-13|Method and apparatus for detecting dimmer phase angle and selectively determining universal input voltage for solid state lighting fixtures|

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