Abstract:
A power factor controller (PFC) for an electrical load such as LED lighting includes a power factor correcting converter for generating a sinusoidal input current. The PFC further includes a programmable controller for estimating a phase shifted multiplier. A current regulator generates a desired PFC current in response to an input voltage, an output load and the phase shifted and subsequently blanked multiplier. The electrical load operates in response to the sinusoidal input current based at least partially on the desired PFC current.

Description:
BACKGROUND 
     The subject matter of this disclosure relates generally to power factor correction, and more particularly, to a system and method for compensating for the leading current in an electrical load such as an LED driver input during light loading of the LED driver. 
     Power factor correctors (PFCs) are well known. Boost converters, Flyback converters, and other topologies are generally used to provide power factor correction for devices powered from an AC line. Input capacitors are typically placed both before and after the rectifier in a boost or other PFC converter to control electro-magnetic interference (EMI). The input capacitors adversely affect power factor (PF). 
       FIG. 1  is a schematic diagram illustrating a typical power factor corrector  10  that includes EMI reduction capacitors C 1  and C 2 . A current regulator I PFC  regulates the PFC converter current at the input to an LED driver, not shown. The LED driver input current I IN =(I PFC +C 1 ωV m  cos ωt)·sign(V in (t))+C 2 ωV m  cos(ωt), where I PFC  is regulated to a sinusoid in most cases. However, at high line voltages and light loading conditions, the capacitor currents dominate, causing poor PF. 
       FIG. 2  is a graph illustrating several waveforms, including instant power  18 , ideal PFC current or reference current signal  20  after a diode rectifier, converter input current  22 , power factor capacitor current  24  and the input voltage  26 . The waveforms shown correspond to regulated current waveforms that are typical under light loading conditions. The net input current is the sum and leads the PFC converter applied voltage. The current in capacitors C 1  and C 2  for example, causes the input current shape to not align with the input voltage at light loads, and becomes worse at high line. 
     Known methods of achieving good PF at the input to an LED driver are limited in both scope and application. Applicable methods usually involve sensing the capacitor current and closing the loop to control the average input current with a feedback loop. This method however, does not translate to other known methods of power factor correction, such as a boundary conduction mode boost or a discontinuous mode Flyback converter. A need exists therefore, for a technique of controlling PF at the input to an LED driver that is not limited in both scope and application, such that the technique can be applied to a broader class of control methods. 
     BRIEF DESCRIPTION 
     According to one embodiment, a power factor controller (PFC) for light emitting diode (LED) lighting, comprises: 
     a boost converter for generating a boost current; 
     a power converter for generating a specific current as a programmable current source; 
     a programmable controller for estimating a phase shifted multiplier with blanking for a specific time interval; 
     a current regulator for generating a desired PFC current in response to an input voltage, an output load and a subsequently derived phase shifted multiplier; and 
     an LED driver that operates in response to a desired LED input current based at least partially on the desired PFC current. 
     According to another embodiment, a method of controlling power factor (PF) for light emitting diode (LED) lighting, comprises: 
     generating a sinusoidal input current via a boost converter, a discontinuous mode Flyback converter, or a like converter; 
     calculating a phase shifted and blanked multiplier via a programmable controller; 
     regulating the sinusoidal input current based on the phase shifted and blanked multiplier to generate a desired power factor control (PFC) current therefrom; and 
     operating an LED driver in response to a desired input current based at least partially on the desired PFC current. 
     According to yet another embodiment, a power factor controller (PFC) comprises: 
     a boost converter, a discontinuous mode Flyback converter, or like power factor correction topology based converter for generating a programmed current; 
     a programmable controller for estimating a phase shifted and blanked multiplier; and 
     a current regulator for generating a desired light emitting diode (LED) driver current based at least partially on the programmed current and the phase shifted and blanked multiplier. 
    
    
     
       DRAWINGS 
       These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings, wherein: 
         FIG. 1  is a schematic diagram illustrating a common input filter and power factor current regulator for generating a regulated sinusoidal current; 
         FIG. 2  is a graph illustrating several waveforms including instant power, input voltage, a power factor capacitor current, current the capacitor C 1  depicted in  FIG. 1 , and a reference current for programming the power factor corrector current; 
         FIG. 3  is a graph illustrating a desired PFC current that is based on a desired input current and a power factor corrector input capacitor current, assuming no rectifier is present; 
         FIG. 4  is a block diagram illustrating a system for controlling a power factor of a sinusoidal AC input current for light emitting diode loads, according to one embodiment; 
         FIG. 5  is a block diagram illustrating a microcontroller that uses input voltage and current switch sense input signals to generate a phase shifted sine wave signal that is transmitted to a multiplier input of an LED driver controller to control the LED driver, according to one embodiment; 
         FIG. 6  is a graph illustrating several waveforms including input voltage, a power factor correction current, current the capacitor C 1  depicted in  FIG. 1 , and a reference current ( 62 ) for programming a power factor controller current, but with the shifted and blanked reference current ( 62 ) corresponding to a shifted and blanked multiplier, yielding a much improved power factor; and 
         FIG. 7  is a graph illustrating an actual waveform of a phase shifted and blanked multiplier with a resulting input current. 
     
    
    
     While the above-identified drawing figures set forth particular embodiments, other embodiments of the present invention are also contemplated, as noted in the discussion. In all cases, this disclosure presents illustrated embodiments of the present invention by way of representation and not limitation. Numerous other modifications and embodiments can be devised by those skilled in the art which fall within the scope and spirit of the principles of this invention. 
     DETAILED DESCRIPTION 
     Looking again at  FIG. 1 , a typical arrangement is shown for a power factor correction front end  10  in an LED driver or AC/DC rectifier. An AC line  12  feeds into a diode rectifier (or equivalent bridgeless rectifier configuration)  14  with an arrangement of passive elements forming an input filter. This arrangement subsequently feeds a boost converter or Flyback converter or similar regulator  16  that can shape the current draw according to a programmed reference. 
     The concepts described herein can be better understood by first considering the simplified case where one ignores the rectifier  14 .  FIG. 3  is a graph illustrating a desired PFC current  30  that is based on a desired LED driver or other load input current  32  and a PFC stage current  34 . With reference again to  FIG. 1 , without the rectifier  14 , the capacitors C 1  and C 2  coalesce into one capacitor, that we shall refer to as C IN . Thus, the desired PFC current  30  produced at the regulator  16  to ensure a perfect PF at the LED drive or load input can be determined by assuming
 
desired LED driver input current  I   IN ( t )= I   M  sin(ω t ) and  Eq. 1
 
PFC converter capacitor current  I   CAP ( t )= C   IN   dV   IN ( t )/ dt=C   IN   V   M  cos(ω t )  Eq. 2
 
and thus, the desired PFC current  I   PFC ( t )= I   M  sin(ω t )− C   IN   V   M  cos(ω t ).  Eq. 3
 
     It is now seen that the desired PFC current  18  can be represented as 
                         I   PFC     ⁡     (   t   )       =       I   PK     ⁢     sin   ⁡     (       ω   ⁢           ⁢   t     -     π   2     +   Ø     )           ,     if   ⁢           ⁢   Ø   ⁢           ⁢   is   ⁢           ⁢     known   .               Eq   .           ⁢   4               
The desired LED driver input current can be obtained by adding the desired PFC current (I PFC )  30  to the boost converter capacitor current  34 .
 
     If the load is modeled as a resistor, R EQ , then
 
Ø=tan −1 (½ πFR   EQ   C   IN );  Eq. 5
 
and
 
 Z   EQ   =R   EQ ∥(½ FR   EQ   C   IN )  Eq. 6
 
which leads to I PFC (t)=I PK  sin(ωt−π/2+Ø) which is the desired result as shown in Eq. 4. This result matches the desired PFC current wave shape exactly and is a phase shifted scaled version of the input sinusoid and provides an estimate of the required phase shift. This result assumes that no rectifier  14  is present, and is provided as an illustration to assist in better understanding the concepts and principles described herein.
 
     The foregoing concepts are now extended to the case where the diode rectifier  14  is included. It can be appreciated that the current cannot flow in both directions once the rectifier  14  is added. The PFC current becomes purely positive, and assuming this case, the input current in  FIG. 1  now becomes
 
 I   IN ( t )=( I   PFC ( t )+ C   1   ωV   m  cos(ω t ))·sign( V   in ( t )+ C   2   ωV   m  cos(ω t )  Eq. 7
 
The signum function provides an unfolding mechanism. It is then desired to realize an input current I IN (t)=I M  sin(ωt), such that the delivered output power, assuming full efficiency, is P OUT =V M I M /2. Thus, I PFC (t) must be chosen such that (I PFC (t)+C 1 ωV m  cos(ωt))·sign)V in (t)+C 2 ωV m  cos(ωt)≈I m  sin(ωt). Looking at  FIG. 3 , one can see that to compensate for the leading capacitor current with the rectifier  14 , the programmed PFC current has to go negative in the initial phase. Since this is not possible with a rectifier, the best one can do is to set the current to zero to create a blanking phase. Thus, compensating for the nonlinearity now necessitates the introduction of the blanking phase in addition to the phase shift.
 
     The blanking and phase shift can be implemented according to one embodiment with analog circuitry or can be programmed according to another embodiment, for example, using a digital microcontroller. The effect of the blanking and phase shift is shown in  FIG. 6 , described in further detail herein, in which the input current is now aligned with the input voltage. 
       FIG. 4  is a simplified block diagram illustrating a system  40  for controlling a power factor of a sinusoidal input current during light loading of one or more LEDs  42 , according to one embodiment. The system  40  comprises a boost or similar PFC converter  10  that includes a rectifier section  14  followed by an EMI reduction capacitor  44 , such as described for one embodiment with reference to  FIG. 1 . The system  40  further comprises a current regulator  16  and a PFC controller  46  that is programmed to calculate a phase shifted multiplier such as the phase shifted scaled version of an input sinusoid represented in Eq. 4. An appropriate blanking interval ( FIG. 6 , numeral  63 ) such as described herein is also included. The LED load(s)  42  have output power changes based on dimming inputs  48  from a user. The LED load power changes may be fed back to the PFC controller  46  as load feedback dimming signals  49 . These feedback signals  49  allow the PFC controller  46  to estimate R EQ , discussed herein with reference to  FIG. 2 , and further to compute the phase shifted multiplier. 
     According to one embodiment, a microcontroller  50 , such as depicted in  FIG. 5 , is used for power factor control; and a phase shifted sine/multiplier  52  generated by the microcontroller  50  is transmitted to a multiplier input section/pin  54  of an LED driver/controller  56 , thus improving the PF of the LED drive/load input signal. More specifically,  FIG. 5  is a block diagram illustrating a microcontroller  50  that uses input voltage and load current switch sense input signals  58 ,  59  to generate a phase shifted sine wave signal  52  that is communicated to the multiplier input pin  54  of the LED driver/controller  56  for controlling LED driver loads, according to one embodiment. 
       FIG. 6  is a graph illustrating a boost converter regulated output current  60  that is commanded by a shift multiplier  62  to generate a desired PFC controller current, according to one embodiment. Subsequent to processing, the boost or similar PFC converter regulated output current  60  and the LED driver input voltage  64  are in sync with each other. A dip  66  in the boost or similar PFC converter regulated output current  60  is caused by a zero crossing associated with the shift multiplier  62 , and has minimal effect on the LED driver input current. 
     The embodiments described herein assume that PFC current can be shaped. It can be appreciated that a line voltage zero crossing may prevent some portion of the PFC current from being shaped, such as the portion  66  depicted in  FIG. 6 . The embodiments described herein may also use load current estimates. According to some aspects, the load current(s) can be estimated from secondary, or input current(s), using a resistor in series with a boost switch. 
     According to one embodiment, an LED driver microcontroller employs a digital to analog converter (DAC) that can generate a sine wave and achieve good resolution at 60 Hz, even if the DAC has low resolution. Such embodiments can be used to accurately determine the input current and input voltage in a manner that can be used to estimate the PFC current I PFC  using the principles described herein. 
       FIG. 7  is a graph illustrating a scaled multiplier  70  that is synced to an AC line  72 . The scaled multiplier  70  compensates for the capacitor current during the first part of the cycle that causes the line current  74  to be out of sync with the line voltage  72 . According to some embodiments, the principles described herein can be used to achieve peak current control or average current control. Partial shaping allows insertion of capacitor compensation at desired points. Further, programmable insertion can advantageously make the compensation a function of line and load variables, e.g. current and voltage. 
     While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.