Abstract
A light-emitting diode (LED) luminaire comprising two types of LEDs, a switching circuit, a signal generating circuit, and an LED driving circuit is used to replace a conventional luminaire with a severe temporal light artifact. The switching circuit and the LED driving circuit are configured to reduce a low-frequency ripple associated with AC mains. The signal generating circuit is configured to produce two sets of modulation signals with a phase difference of 180 degrees between the two sets of modulation signals, which are then embedded in the LED driving current to drive the two types of LEDs, resulting in imperceptible flicker at a temporal modulation frequency as a result of color mixing of the two types of LEDs and persistence of vision, thereby drastically reducing eyestrain, visual discomfort, etc.
Claims
1. A light-emitting diode (LED) luminaire, comprising: one or more LED arrays; at least one full-wave rectifier configured to couple to alternate-current (AC) mains and convert a line voltage from the AC mains into a first direct-current (DC) voltage; a switching circuit comprising a control device, a diode rectifier circuit, and a first electronic switch controlled by the control device and configured to modulate the first DC voltage into a variable DC voltage at a switching frequency; a signal generating circuit comprising a phase shifter circuit and configured to produce a first set of signal and a second set of signal both at a predetermined temporal modulation frequency; and an LED driving circuit comprising two sets of drivers configured to produce two sets of driving current, in response to the first set of signal and the second set of signal, to drive the one or more LED arrays, wherein: the phase shifter circuit is configured to shift a first phase of the first set of signal into a second phase of the second set of signal; the switching circuit is configured to convert the first DC voltage into a second DC voltage and to operate the two sets of drivers; the two sets of drivers are further configured to respectively produce a third DC voltage and a fourth DC voltage each with a lower electric potential than the second DC voltage; and the two sets of drivers respectively comprise a second electronic switch and a third electronic switch respectively configured to modulate the two sets of driving current, in response to the first set of signal and the second set of signal, to drive the one or more LED arrays.
2. The light-emitting diode (LED) luminaire of claim 1, wherein the one or more LED arrays comprise a first type of LEDs and a second type of LEDs.
3. The light-emitting diode (LED) luminaire of claim 2, wherein either of the first set of signal and the second set of signal comprises a modulation signal at the predetermined temporal modulation frequency with a phase difference angle of nominal 180 degrees between the first phase and the second phase.
4. The light-emitting diode (LED) luminaire of claim 3, wherein the third DC voltage, the fourth DC voltage, and the two sets of driving current in response to the first set of signal and the second set of signal are further configured to respectively drive the first type of LEDs and the second type of LEDs.
5. The light-emitting diode (LED) luminaire of claim 4, wherein each of the two sets of drivers further comprises a low-pass filter circuit configured to remove high frequency components higher than the predetermined temporal modulation frequency in either of the third DC voltage or the fourth DC voltage, resulting in an illumination from the first type of LEDs and the second type of LEDs with less visual discomfort to luminaire users.
6. The light-emitting diode (LED) luminaire of claim 5, wherein the diode rectifier circuit provides a primary output port, wherein the low-pass filter circuit in either of the two sets of drivers provides a secondary output port, wherein the third DC voltage and the fourth DC voltage are respectively taken between the primary output port and the secondary output port in each of the two sets of drivers, thereby canceling out a common fluctuating AC component in the third DC voltage and the fourth DC voltage, and wherein the third DC voltage and the fourth DC voltage are respectively applied to the first type of LEDs and the second type of LEDs with reduced flickers, thereby reducing eyestrain of the luminaire users.
7. The light-emitting diode (LED) luminaire of claim 6, wherein each of the first set of signal and the second set of signal comprises square waves comprising a series of pulses with a duty cycle of 50% and a predetermined period, wherein the two sets of driving current comprise two modulation signals both associated with the predetermined period, and wherein respective light emissions from the first type of LEDs and the second type of LEDs in response to the two sets of driving current comprise the predetermined period with a phase difference angle of nominal 180 degrees, same as the phase difference angle between the two modulation signals respectively applied on the first type of LEDs and the second type of LEDs.
8. The light-emitting diode (LED) luminaire of claim 7, wherein overall light emissions in combination from the first type of LEDs and the second type of LEDs comprise a reduced percent flicker due to the two modulation signals.
9. The light-emitting diode (LED) luminaire of claim 2, wherein the first type of LEDs and the second type of LEDs respectively emit a first white light at a nominal correlated color temperature (CCT) of 3500 K and a second white light at a nominal CCT of 5000 K.
10. The light-emitting diode (LED) luminaire of claim 9, wherein a resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates.
11. The light-emitting diode (LED) luminaire of claim 2, wherein the first type of LEDs and the second type of LEDs respectively emit a first white light at a nominal correlated color temperature (CCT) of 3000 K and a second white light at a nominal CCT of 6500 K.
12. The light-emitting diode (LED) luminaire of claim 11, wherein a resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates.
13. The light-emitting diode (LED) luminaire of claim 2, wherein the first type of LEDs and the second type of LEDs respectively emit a first white light at a nominal correlated color temperature (CCT) of 2700 K and a second white light at a nominal CCT of 6500 K.
14. The light-emitting diode (LED) luminaire of claim 13, wherein a resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates.
15. The light-emitting diode (LED) luminaire of claim 1, wherein the predetermined temporal modulation frequency is a nominal 40 Hz.
16. The light-emitting diode (LED) luminaire of claim 1, wherein the signal generating circuit comprises a Bluetooth system-on-chip (SOC) circuit.
17. The light-emitting diode (LED) luminaire of claim 2, wherein the one or more LED arrays further comprise a third type of LEDs, wherein the first set of signal and the second set of signal are configured to modulate the two sets of driving current to drive the first type of LEDs and the second type of LEDs, and wherein the third type of LEDs are configured to be driven with a constant current, thereby increasing a background light in an illumination area, consequently decreasing a possibility of light flickers on the first type of LEDs and the second type of LEDs to be detected with a reduced percent flicker.
18. The light-emitting diode (LED) luminaire of claim 17, wherein the third type of LEDs emit a white light at a nominal correlated color temperature (CCT) of 4000 K.
19. The light-emitting diode (LED) luminaire of claim 2, wherein the first type of LEDs comprise multiple LEDs saturated at red, saturated at green, and saturated at blue, and wherein the second type of LEDs emit a white light at a nominal correlated color temperature (CCT) of 4000 K, and wherein a resultant illumination from the first type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing for the multiple LEDs along a Planckian locus in color coordinates.
20. The light-emitting diode (LED) luminaire of claim 2, wherein the first type of LEDs comprise multiple LEDs saturated at red and at green, wherein the second type of LEDs comprise LEDs saturated at blue, and wherein a resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal correlated color temperature (CCT) of 4000 K as a result of color mixing for the first type of LEDs and the second type of LEDs along a Planckian locus in color coordinates.
21. A light-emitting diode (LED) luminaire, comprising: one or more LED arrays; at least one full-wave rectifier configured to couple to alternate-current (AC) mains and convert a line voltage from the AC mains into a first direct-current (DC) voltage; a switching circuit comprising a control device, a diode rectifier circuit, and a first electronic switch controlled by the control device and configured to modulate the first DC voltage into a variable DC voltage at a switching frequency; a signal generating circuit configured to produce a modulation signal at a predetermined temporal modulation frequency; and an LED driving circuit comprising at least one driver configured to produce at least one set of driving current, in response to the modulation signal, to drive the one or more LED arrays, wherein: the switching circuit is configured to convert the first DC voltage into a second DC voltage and to operate the at least one driver; the at least one driver is further configured to produce a third DC voltage with a lower electric potential than the second DC voltage; and the at least one driver further comprises a second electronic switch configured to modulate the at least one set of driving current, in response to the modulation signal, to drive the one or more LED arrays.
22. The light-emitting diode (LED) luminaire of claim 21, wherein the one or more LED arrays comprise a first portion of LEDs and a second portion of LEDs, wherein the modulation signal is configured to modulate the at least one set of driving current to drive the first portion of LEDs, and wherein the second portion of LEDs are configured to be driven with a constant current, thereby increasing a background light in an illumination area, consequently decreasing a possibility of light flickers on the first portion of LEDs to be detected with a reduced percent flicker.
23. The light-emitting diode (LED) luminaire of claim 21, wherein the predetermined temporal modulation frequency is a nominal 65 Hz.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] Non-limiting and non-exhaustive embodiments of the present disclosure are described with reference to the following figures, wherein like names refer to like parts but their reference numerals differ throughout the various figures unless otherwise specified. Moreover, in the section of detailed description of the invention, any of a primary, a secondary, a first, a second, a third, and so forth does not necessarily represent a part that is mentioned in an ordinal manner, but a particular one.
[0014] FIG. 1 is a first embodiment of an LED luminaire according to the present disclosure.
[0015] FIG. 2 is a second embodiment of an LED luminaire according to the present disclosure.
[0016] FIG. 3 is a third embodiment of an LED luminaire according to the present disclosure.
[0017] FIG. 4 is an example of waveforms of visual stimuli used in simulating a light flicker according to the present disclosure.
[0018] FIG. 5 is an example of two square waves used to drive LED arrays according to the present disclosure.
[0019] FIG. 6 is a visual flicker waveform relative to a reference visual stimulus according to the present disclosure.
[0020] FIG. 7 is a visual flicker waveform relative to a reference stimulus with a reduced brightness flicker according to the present disclosure.
[0021] FIG. 8 is various voltage waveforms in a driver according to the present disclosure.
[0022] FIG. 9 is a first example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure.
[0023] FIG. 10 is a second example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure.
[0024] FIG. 11 is a third example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure.
[0025] FIG. 12 is a fourth example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure.
[0026] FIG. 13 is an example of various spectral power distributions according to the present disclosure.
DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS
[0027] FIG. 1 is a first embodiment of an LED luminaire according to the present disclosure. In FIG. 1, the LED luminaire 200 comprises one or more LED arrays 214 and 215, a switching circuit 300, and an LED driving circuit 400. The LED luminaire 200 further comprises at least two electrical conductors L and N, at least one full-wave rectifier 201, a signal generating circuit 202, and at least one quartz crystal circuit 203. The at least two electrical conductors L and N are configured to couple to a line voltage from the AC mains. The at least one full-wave rectifier 201 is configured to convert the line voltage into a first DC voltage. The signal generating circuit 202 is configured to produce a first set of signal and a second set of signal both at a predetermined temporal modulation frequency. The at least one quartz crystal circuit 203 is configured to generate an oscillation frequency.
[0028] The switching circuit 300 comprises a transformer 301, a first control device 302, a first ground reference 254, a first electronic switch 303 controlled by the first control device 302, a current control resistor 304, and a diode rectifier circuit 305. The first electronic switch 303 is configured to modulate the first DC voltage into a variable DC voltage at a switching frequency. The transformer 301 comprises a primary winding 307, a secondary winding 308, and an auxiliary winding 309. When the first electronic switch 303 is closed, an input current flows into the primary winding 307 with energy stored in its increasing magnetic field, and the diode rectifier circuit 305 is reverse biased. When the first electronic switch 303 is opened, the diode rectifier circuit 305 conducts to generate energy pulses that can be transmitted via the secondary winding 308. That is to say that the diode rectifier circuit 305 is configured to provide energy pulses when the first electronic switch 303 is turned off. The first electronic switch 303 is a key of the switching circuit 300 to provide the variable DC voltage, ultimately regulating an output voltage and current.
[0029] In FIG. 1, the switching circuit 300 is coupled to the at least one full-wave rectifier 201 and configured to convert the first DC voltage into the variable DC voltage at the switching frequency, ultimately being rectified and filtered into a second DC voltage by the diode rectifier circuit 305 and a capacitor 306. The second DC voltage appears at a port A. In FIG. 1, the switching circuit 300 further comprises a high voltage port 311 coupled to the primary winding 307, and a voltage feedback circuit 320 coupled to the auxiliary winding 309. The high voltage port 311 is configured to provide a startup voltage to operate the first control device 302. When the primary winding 307 is operating, the voltage feedback circuit 320 receives a power from the auxiliary winding 309 with an auxiliary voltage to sustain an operation of the first control device 302. The voltage feedback circuit 320 may comprise a diode. When the startup voltage decreases due to its increased internal operations and controls, and when the auxiliary voltage is higher than the startup voltage, the diode in the voltage feedback circuit 320 conducts to supply a current to sustain operations of the first control device 302. The function of the voltage feedback circuit 320 is essential for the first control device 302 to operate properly because the switching circuit 300 has a wide range of operating voltages, for example, 110, 277, or 347 VAC from the AC mains in North America and because the line voltage from the AC mains goes to zero in each AC cycle. The voltage feedback circuit 320 is thus needed to pump in energy in time and to sustain the operating voltage and to ensure no strobing occurred when the one or more LED arrays 214 and 215 are operating. That is, the voltage feedback circuit 320 is configured to draw energy from the auxiliary voltage to sustain operation of the first control device 302.
[0030] In FIG. 1, the LED driving circuit 400 comprises a second ground reference 255 electrically isolated from the first ground reference 254 using the transformer 301, and two sets of drivers 410 and 420 configured to produce two sets of driving current in response to the first set of signal and the second set of signal to drive the one or more LED arrays 214 and 215. Each of the two sets of drivers 410 and 420 respectively comprises a second electronic switch 411 and a third electronic switch 421 respectively configured to modulate the two sets of driving current in response to the first set of signal and the second set of signal to respectively drive the one or more LED arrays 214 and 215.
[0031] In FIG. 1, each of the two sets of drivers 410 and 420 further respectively comprises a second control device 412 and a third control device 422. Each of the two sets of drivers 410 and 420 further respectively comprises a first low-pass filter 413 and a second low-pass filter 423 both coupled to the diode rectifier circuit 305 and configured to remove high frequency components higher than the predetermined temporal modulation frequency in either of the third DC voltage or the fourth DC voltage, thereby with a resulting illumination from the one or more LED arrays 214 and 215 free of the high frequency components, which may reduce human biological effects. The high frequency components may come from a modulation via the signal generating circuit 202. Each of the first low-pass filter 413 and the second low-pass filter 423 respectively comprises an inductor 414 and 424 and a capacitor 415 and 425. And an output port B of the first low-pass filter 413 is taken between the inductor 414 and the capacitor 415. Similarly, an output port C of the second low-pass filter 423 is taken between the inductor 424 and the capacitor 425. The second DC voltage, which is with respect to the second ground reference 255, comprises a low-frequency variation (i.e., a ripple) associated with the AC mains because the line voltage is sinusoidal at a nominal frequency of 50 Hz or 60 Hz. The DC voltages at the port B and the port C comprise the same low-frequency variation. The third DC voltage is taken between the port A and B and filtered by a capacitor 416, whereas the fourth DC voltage is taken between the port A and C and filtered by a capacitor 426. The same variations are compensated, leading to the third DC voltage and the fourth DC voltage free of the low-frequency variation with a reduced low-frequency current ripple to drive the one or more LED arrays 214 and 215 with a flicker-reduced light emission. That is, by taking an electric potential difference between the second DC voltage and the output of the low-pass filter as the third DC voltage, the low-frequency ripple is suppressed to produce the third DC voltage with the ripple-reduced LED driving current, so does the fourth DC voltage. In other words, the LED driving circuit 400 can provide one or more sets of output current required to operate the one or more LED arrays 214 and 215 with a luminous flux that has a suppressed flicker. Please note that the low-frequency flicker, referred to a nominal flicker frequency of 100 Hz or 120 Hz, depending on a line frequency of the AC mains used, may cause eyestrain to luminaire users. The suppressed flicker may release such eye discomfort.
[0032] In FIG. 1, the signal generating circuit 202 is coupled to the at least one quartz crystal circuit 203 and configured to generate the first set of signal and the second set of signal both at a predetermined temporal modulation frequency. When both the first set of signal and the second set of signal are modulated at the predetermined temporal modulation frequency, a first modulated signal goes to the first set of driver 410 whereas a second modulated signal goes to the second set of driver 420. The first modulated signal and the second modulated signal, which are 180 degrees out of phase, are respectively sent to the second control device 412 and the third control device 422 to control the second electronic switch 411 and the third electronic switch 421 to turn on and off so as to modulate the first modulated signal and the second modulated signal into the third DC voltage and the fourth DC voltage, which are used to drive the one or more LED arrays 214 and 215. In other words, the first modulated signal and the second modulated signal respectively has a first phase and a second phase. A phase difference angle between the first phase and the second phase is 180 degrees. Specifically, the first modulated signal and the second modulated signal may be referred to as two complementary modulation signals.
[0033] In FIG. 1, the one or more LED arrays 214 and 215 respectively comprise a first type of LEDs and a second type of LEDs, which have different spectral power distributions (SPD) from each other. As will be depicted below, the one or more LED arrays 214 and 215 respectively emit a first set of emission and a second set of emission each comprising individual flickers according to the first modulated signal and the second modulated signal. But a mixture of the first set of emission and the second set of emission exhibits an imperceptible flicker with the temporal modulation frequency at a benign frequency which has potential effects to entrain gamma oscillations in luminaire users' brains, thereby improving brain functions. As mentioned, the mixture of the first set of emission and the second set of emission exhibits a different color coordinate or correlated color temperature (CCT) as a result of color mixing between the first set of emission and the second set of emission.
[0034] Each of the first modulated signal and the second modulated signal may exhibit like a series of binary data. To obtain a best signal-to-noise ratio, it may be necessary to modulate the signals onto a carrier wave with a fixed carrier frequency. Binary symbol 1 is represented by transmitting a sinusoidal carrier wave of fixed amplitude and the fixed frequency for on duration, whereas binary symbol 0 is represented by switching off the carrier for off duration. A modulation process corresponds to switching the amplitude. Such a signaling technique is similar to amplitude-shift keying (ASK). At a receiving end of either the first set of driver 410 or the second set of driver 420, the carrier waves must be removed before going into the two sets of LED driving current. This is where the first low-pass filter 413 and the second low-pass filter 423 come in to remove the high frequency components of the carrier waves. The signal generating circuit 202 may comprise a Bluetooth system-on-chip (SOC) circuit configured to send such an ASK signal.
[0035] FIG. 2 is a second embodiment of an LED luminaire according to the present disclosure. In FIG. 1, the LED driving circuit 400 comprises the two sets of drivers, 410 and 420, configured to produce two sets of driving current in response to the first set of signal and the second set of signal to drive the one or more LED arrays 214 and 215. As mentioned above, when a phase shift of a nominal 180 degrees is introduced between the first set of signal and the second set of signal, the mixture of light emissions from the one or more LED arrays 214 and 215 exhibits an imperceptible flicker. However, the imperceptible flicker sometimes cannot satisfy customers who have acute visions to see a tiny flicker. In that case, the LED luminaire must include an option to further improve flicker imperceptibility. In FIG. 2, the LED driving circuit 400 further comprises one or more LED arrays 216 in addition to the one or more LED arrays 214 and 215 and a third set of driver 430 in addition to the two sets of drivers 410 and 420. The third set of driver 430 is configured to produce a third set of driving current without a modulated signal to drive the one or more LED arrays 216. In this case, the signal generating circuit 202 may send the binary symbol 0 all the way to the third set of driver 430, switching off the carrier. In other words, the one or more LED arrays 216 are driven with a constant current. No matter whether the first modulated signal and the second modulated signal are present or not, the mixture of the first set of emission and the second set of emission exhibits a different color coordinate or CCT from the first set of emission and the second set of emission, so called color fusion. Simply put, the one or more LED arrays 216 comprise a third type of LEDs of which light emissions exhibit a color-fusion color. The light emissions at the color-fusion color from the one or more LED arrays 216 is used to increase a background light in an illumination area, which consequently decreases a possibility of a light flicker on the first type of LEDs and the second type of LEDs due to the first modulated signal and the second modulated signal to be detected with a reduced percent flicker. In FIG. 2, the one or more LED arrays 215 can be removed if there is no need to modulate the second set of LED driving current to reduce apparent flickers (to be depicted in FIG. 3). In that case, a temporal modulation frequency may be above CFF, and such a flicker cannot be perceived by most people.
[0036] FIG. 3 is a third embodiment of an LED luminaire according to the present disclosure. In FIG. 3, the LED luminaire 200 is almost the same as the one in FIG. 1 except that the LED driving circuit 400 comprises a first driver 410 and a second driver 430 and the one or more LED arrays 214 and 216. The first driver 410 is configured to produce one set of driving current in response to one set of signal provided by the signal generating circuit 202 to drive the one or more LED arrays 214 whereas the second driver 430 is configured to produce a constant driving current in response to a signal provided by the signal generating circuit 202 to drive the one or more LED arrays 216. As mentioned above, the imperceptible flicker even above CFF sometimes cannot satisfy customers who have acute visions to see a tiny flicker. In that case, the LED luminaire 200 must include an option to further improve flicker imperceptibility. In FIG. 3, light emissions from the one or more LED arrays 216 are used to increase a background light in an illumination area, which consequently decreases a possibility of a light flicker on the one or more LED arrays 214 due to the one set of signal modulated to be detected with a reduced percent flicker.
[0037] FIG. 4 is an example of waveforms of visual stimuli used in simulating a light flicker according to the present disclosure. In FIG. 3, two waveforms 901 and 902 represent two visual stimuli. Experimental results show that a flicker response linearly follows the visual stimuli. In FIG. 4, each of the waveforms can be expressed as g(t)=E(1+m* sin(t+)), where g(t) comprises a steady-state component, E (denoted as 931), providing a retinal illuminance E=const., t denoting time, denoting an angular frequency of a flicker input to the human's eye, a phase shift relative to a zero phase reference, and a sinusoidally modulated component with an amplitude corresponding to retinal illuminance mE (denoted as 932) with 0<m<1. In FIG. 4, the waveform 901 has a period 933, which is 2/, related to a temporal modulation frequency. The waveform 902 has a phase shift (i.e., 180 degrees) relative to the waveform 901. There are seven factors that determine the ability to detect a flicker by a human's eye: 1) the temporal modulation frequency; 2) the amplitude or depth of the modulation (i.e., mE); 3) the average (or maximum) illumination intensity (i.e., E); 4) the wavelength (or wavelength range) of the illumination (this factor and the illumination intensity can be combined into a single factor for humans for which the sensitivities of rods and cones are known as a function of wavelength using the luminous flux function); 5) the position on the retina at which the stimulation occurs (due to the different distribution of photoreceptor types at different positions); 6) the degree of light or dark adaptation, i.e., the duration and intensity of previous exposure to background light, which affects both the intensity sensitivity and the time resolution of vision; 7) physiological factors such as age and fatigue. It is important to note that the phase shift may be associated with latency of a visual system of the human's eye. In practice, it is necessary to introduce the phase shift in addition to (i.e., 180 degrees) to compensate a phase difference between the two stimuli in the visual system mediating brightness and chromatic perceptions, so as to reduce visual flickers.
[0038] FIG. 5 is an example of two square waves used to drive LED arrays according to the present disclosure. In FIG. 5, a first square wave 801 and a second square wave 802 are used as two stroboscopic stimuli with 100% modulation depth, amplitude 831, and a period 832. The first square wave 801 and the second square wave 802 are 180 degrees out of phase (denoted as 833) from each other. When such two stroboscopic stimuli are modulated in the first type of LEDs and the second type of LEDs and mixed in a color domain, a resultant mixture becomes a third color and a reduced percent flicker (see FIG. 7). In FIG. 5, each of the first set of signal (i.e., the first square wave 801) and the second set of signal (i.e., the second square wave 802) comprises a series of pulses with a duty cycle of 50% and a predetermined period (i.e., the period 832). A reciprocal of the predetermined period is the predetermined temporal modulation frequency. The two sets of driving current comprise two modulation signals both associated with the predetermined period. Respective light emissions from the first type of LEDs and the second type of LEDs in response to the two sets of driving current comprise the predetermined period with the phase difference angle of nominal 180 degrees, same as the phase difference angle between the two modulation signals respectively applied on the first type of LEDs and the second type of LEDs.
[0039] FIG. 6 is a visual flicker waveform relative to a reference stimulus according to the present disclosure. In FIG. 6, a reference modulated stimulus waveform 701 and a detected flicker voltage waveform 702 when there is only one reference modulated stimulus 701 is present. The reference modulated stimulus waveform 701 comprises amplitude 731 and a temporal modulation period 732. As can be seen, the detected flicker voltage waveform 702 simply follows the reference modulated stimulus waveform 701, and both waveforms are in phase. A calculated percent flicker is as high as 70% due to the temporal modulation by the reference modulated stimulus 701.
[0040] FIG. 7 is a visual flicker waveform relative to a reference stimulus with a reduced brightness flicker according to the present disclosure. In FIG. 7, a detected flicker voltage waveform 602 is 180 degrees out of phase with a reference modulated stimulus waveform 601 when the two reference modulated stimuli (as in FIG. 5) are present. The reference modulated stimulus waveform 601 comprises amplitude 631 and a temporal modulation period 632. As can be seen, the detected flicker voltage waveform 602 simply follows the reference modulated stimulus waveform 601 but with a phase shift 633 of 180 degrees. This is because the amplitude of the other modulated stimulus is larger than that of the reference modulated stimulus (i.e., the waveform 601). The detected flicker voltage waveform 602 shows a reduced brightness flicker relative to the detected flicker voltage waveform 702 in FIG. 6. A calculated percent flicker is as low as 5% due to a compensation effect of two complementary modulated stimuli.
[0041] FIG. 8 is various voltage waveforms according to the present disclosure. In FIG. 8, a second DC voltage waveform 501 comprises a voltage ripple associated with the line voltage. A ripple period 504 is related to the line frequency, which is 8.33 milliseconds (corresponding to 120 Hz). An output voltage waveform 502 from the low-pass filter 413 (FIG. 1) comprises exactly the voltage ripple as in second DC voltage waveform 501. In FIG. 1, the third DC voltage is taken between the second DC voltage and the output voltage of the Low-pass filter 413. In FIG. 8, a third DC voltage waveform 503 shows that the ripple voltage has been removed, leaving with a relatively flat waveform and with a period 505 associated with the modulated stimulus. A calculated percent flicker in the third DC voltage waveform 503 is about 2.6%. This means that taking voltage difference of the second DC voltage and the output voltage from the low-pass filter as a driving voltage (i.e., the third DC voltage) leads to a reduced low-frequency current ripple. In FIG. 8, a light output emission from the one or more LED arrays is sampled and recorded in a plot of 506 with a little apparent flicker, where a period (i.e., time interval) 507 represents 8.33 milliseconds, same as the period 505. A flicker meter has been used to measure a percent flicker, which shows the percent flicker less than 4%. Since the luminance of the one or more LED arrays 214 responds instantaneously to the LED driving current, the reduced low-frequency current ripple causes the luminous output with a reduced low-frequency flicker.
[0042] FIG. 9 is a first example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure. In FIG. 9, a plot 101 is Planckian locus. As depicted in FIG. 1, the first type of LEDs and the second type of LEDs respectively emit a first white light at a nominal CCT of 3500 K and a second white light at a nominal CCT of 5000 K. The chromaticity of the first type of LEDs and the second type of LEDs falls within the corresponding 7-step chromaticity quadrangles as defined in ANSI/NEMA/ANSLG C78.377-2011. A resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates. A plot 102 and a plot 103 represent two complementary modulation signals are applied on the first type of LEDs and the second type of LEDs. The two complementary modulation signals in FIG. 9 may not be scaled. The resultant illumination from the first type of LEDs and the second type of LEDs individually comprises the modulation signal, which causes apparent flickers. But in combination, the resultant illumination exhibits a reduced flicker.
[0043] FIG. 10 is a second example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure. In FIG. 10, a plot 101 is Planckian locus. As depicted in FIG. 1, the first type of LEDs and the second type of LEDs may respectively emit a first white light at a nominal CCT of 3000 K and a second white light at a nominal CCT of 6500 K. The chromaticity of the first type of LEDs and the second type of LEDs falls within the corresponding 7-step chromaticity quadrangles. A resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates. A plot 102 and a plot 103 represent two complementary modulation signals are applied on the first type of LEDs and the second type of LEDs. The two complementary modulation signals in FIG. 10 may not be scaled. The resultant illumination from the first type of LEDs and the second type of LEDs individually comprises the modulation signal, which causes apparent flickers. But in combination, the resultant illumination exhibits a reduced flicker.
[0044] FIG. 11 is a third example of two types of LEDs with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure. In FIG. 11, a plot 101 is Planckian locus. As depicted in FIG. 1, the first type of LEDs and the second type of LEDs may respectively emit a first white light at a nominal CCT of 2700 K and a second white light at a nominal CCT of 6500 K. The chromaticity of the first type of LEDs and the second type of LEDs falls within the corresponding 7-step chromaticity quadrangles. A resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing along a Planckian locus in color coordinates. A plot 102 and a plot 103 represent two complementary modulation signals are applied on the first type of LEDs and the second type of LEDs. The two complementary modulation signals in FIG. 11 may not be scaled. The resultant illumination from the first type of LEDs and the second type of LEDs individually comprises the modulation signal, which causes apparent flickers. But in combination, the resultant illumination exhibits a reduced flicker.
[0045] FIG. 12 is a fourth example of two types of with color coordinates plotted in (u, v) chromaticity diagram according to the present disclosure. In FIG. 12, a human's eye sensitivity gamut is plotted with a plot 101 as Planckian locus. The first type of LEDs comprise multiple LEDs saturated at red, saturated at green, and saturated at blue, whereas the second type of LEDs emit a white light at a nominal CCT of 4000 K. The saturated red, the saturated green, and saturated blue respectively falls at a wavelength of 770 nm, a wavelength of 520 nm, and a wavelength of 480 nm can be controlled to fall within chromaticity quadrangles at a nominal CCT of 4000 K as a result of color mixing of three primary colors, red, green, and blue in color coordinates. A resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K. The two complementary modulation signals (not shown for simplicity) are applied on the first type of LEDs and the second type of LEDs. The resultant illumination from the first type of LEDs and the second type of LEDs individually comprises the modulation signal, which causes apparent flickers. But in combination, the resultant illumination exhibits a reduced chromatic flicker, which has lower critical chromatic flicker frequency (CCFF) than CFF in general, as mentioned above. The CCFF is 28 Hz at 100% modulation for a particular retinal illuminance. The CCFF occurs only when the two modulation signals are 180 degrees out of phase. For a fixed modulation frequency, chromatic flicker is more difficult than brightness flicker to be seen by a normal person. The chromatic flicker may be generated by presenting two stimuli of different colors in a periodically alternating mode. This is one of cases according to present disclosure. At a particular temporal modulation frequency, the two stimuli of different colors will fuse to a single color as mixture of the two stimuli of different colors. In this case, the so called chromatic flicker disappears. The particular temporal modulation frequency is referred to as CCFF. In FIG. 12, the first type of LEDs may comprise multiple LEDs saturated at red and at green whereas the second type of LEDs may comprise LEDs saturated at blue. A resultant illumination from the first type of LEDs and the second type of LEDs exhibits a nominal CCT of 4000 K as a result of color mixing for the first type of LEDs and the second type of LEDs along a Planckian locus in color coordinates.
[0046] FIG. 13 is an example of various spectral power distributions according to the present disclosure. In FIG. 13, the various spectral power distributions (SPDs) are of white light emitted by various white LEDs with CCTs at 2400 K, 2700 K, 3000 K, 3500 K, 4000K, 5000 K, and 6500 K. As can be seen, each of SPDs exhibits variations across the spectrum. The various SPDs show two peak values at approximately 450 nm (in the blue region of the visible spectrum) and in the approximately 525-630 nm range (in the green-yellow area of the visible spectrum), ensuring good color quality (i.e., Ra80 and R.sub.9>0). As a rule, CFF is dependent on color difference whereas CCFF depends on chromaticity difference. The larger the differences, the lower CFF and CCFF. Therefore, by using these white LEDs, imperceptible flicker can be achieved at the modulation frequency of interest, such as 40 Hz or 65 Hz.
[0047] Whereas preferred embodiments of the present disclosure have been shown and described, it will be realized that alterations, modifications, and improvements may be made thereto without departing from the scope of the following claims. Another LED driving circuit with an output voltage and current modulated and embedded in an LED luminaire using various kinds of combinations to accomplish the same or different objectives could be easily adapted for use from the present disclosure. Accordingly, the foregoing descriptions and attached drawings are by way of example only and are not intended to be limiting.
