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Lighting systems Light sources in modern buildings:
characterization, modeling and simulations
Panel Session: New Harmonic Sources in Modern Buildings
1
Jiri Drapela Brno University of Technology, Czech Republic
Roberto Langella Second University of Naples, Iatly
IEEE PES General Meeting 2014, July 27-31, Washington DC
2
Lighting technologies for general lighting in modern buildings
█ About 20% of electricity worldwide is consumed by artificial illumination system, thus by light
sources (lamps) of different types
█ Direction according to market studies
(residential, public buildings and commercial sectors)
High intensity discharge, halogen lighting and incandescent bulbs – in withdrawal
Fluorescent lighting – run over and then withdrawal
LED lighting – taking market, increasing penetration
3
Lighting technologies for general lighting in modern buildings
█ Design of converters for lamps vs. Emissions of harmonic current
Emissions are related to circuitry of supply units (ballast and converters/ drivers) which design is subject to
following factors:
application (replacement of lamps, for designated luminaires, for illumination systems with specific
distribution system, …)
qualities (dimming, communication, etc.)
requirements of related standards
production costs
█ Design variations related to application
integrated design
(converter “inseparable” from lamp)
external converter for specific no. of lamps
converter feeding specific distribution system
with independently controlled lamps
█ Requirements for converters for lamps (standards)
to ensure correct operation of a lamp (fluorescent tube, LED) in all operational states
requirements for safety
EMC requirements – in terms of immunity
– limitation in emissions
conv.
light source
mains
mains
luminaire
conv.
mains luminaire
conv. conv.
luminaire
conv.
4
Lighting technologies for general lighting in modern buildings
█ Direct or indirect requirements on /specifications for ballasts and converters design according to
the (EU) standards (brief overview)
Lamp – performance and safety
specifications
EN 60081 and EN 61195. Double-
capped fluorescent lamps.
EN 61167. Metal halide lamps.
…
Lamp controlgear – general
(particular), performance and
safety requirements
EN 61347-x-y standard series.
EN 60921. Ballasts for tubular
fluorescent lamps.
…
Luminaire – general (particular),
performance and safety
requirements and tests
EN 60598-x-y standard series.
EN 60921. Ballasts for tubular
fluorescent lamps.
…..
Luminaire, controlgear – EMC requirements and tests
EN 61547. EMC Immunity requirements. EN 55015. Radio frequency emission limits.
EN 61000-4-y standard series. EN 61000-3-2. Limits for harmonic current emissions
….
5
with capacitive PFCwith active PFC
+
-
Y
Y Y
NN
rectifier
HPFNPFLPF
with inductive PFC
+
-
circuitcircuit
circuit
N
Y
i
/2
i
/2 /2
i
/2
i
double stage
topology
Single-Stage (S-S)
topology
N
Y Y
EMI Filter
Rectifier Inverter
Driver Ouput stage
230V ~
L
N CB
i
v vB
iI
iLvL
█ Typical circuits of EB for FLs
• screw-based
CFLs (P≤25 W)
• screw-based
CFLs • screw-based CFLs
(small choke –
Discontinuous
Current Conduction
(DCC) - LPF)
• external EB for
LFLs (big choke –
Continuous CC
• external EB
for LFLs
and CFLs
• screw-based
CFLs
• external EB for
CFLs and LFLs
FL is fed from a Half-bridge resonant
voltage source (or from a Push-Pull)
inverter which is supplied from a source of
DC voltage
Electronic Ballast (EB) for Fluorescent Lamps (FLs) - topologies
6
Drivers (power supplies) for LEDs - topologies
█ Typical circuits of Drivers/Power supplies for LEDs
L
N
i
v
CD
CB iL
vL
L
NvB
CB
i
v
iLvL
iILBK
PWM
iL
vL
PWM
iI
iI
iLvL
Cr
Lr1 Lr2
no
n-i
so
late
d
iso
late
d
Voltage
divider, used
for very low
inp. power
There are used the same PFC
techniques as in case of EBs.
A map is at at next slide
Buck conv. – “universal input”; Const.
Current (CC) or Const. Voltage (CV)
output; driver for LP or power LEDs
Flyback conv. – “universal input”; CC
or CV output; driver for power LEDs
or power supply for LED track,
luminaries or lamps
Half-Bridge (HB)
resonant conv. –
“universal input”; CC or
CV output; driver for
power LEDs or power
supply for LED track,
luminaries or lamps
Optimized to supply voltage level;
series string of 10-35 mA LEDs (Low-
Power LEDs)
7
with capacitive PFCwith active PFC
+
-
Y
Y Y
NN
rectifier
HPFNPFLPF
with inductive PFC
+
-
circuitcircuit
circuit
N
Y
i
/2
i
/2 /2
i
/2
i
double stage
topology
Single-Stage (S-S)
topology
N
Y Y
• screw- or other
cap- based
LED lamps
(P≤25 W)
• also external
drivers for high
power apps
(P>25 W)
• external drivers
for LEDs
• screw- or other cap-
based LED lamps
(small choke –
Discontinuous
Current Conduction
(DCC) - LPF)
• external drivers
for LEDs and
power supplies
for tracks,
luminaries or
lamps
• external drivers
for LEDs and
power supplies
for tracks,
luminaries or
lamps
Drivers (power supplies) for LEDs - topologies
█ Typical circuits of Drivers/Power supplies for LEDs – Power Factor Correction
L
NvB
CB
i
v
iLvL
PWM
iI
8
Modeling of lamps with converters
█ Modeling in time domain
█ Full / switching models – even if simplified/ optimized for specific purposes
Utilization of an accurate model of lamp itself if fed from an electronic converter is not
so important for input to input response as the convertor model is. (For Low/Frequency
(LF) conducted disturbances study).
Simulations of switching models behaviour are very time consuming….and thus are
not suitable for response prediction of large systems or for simulation of long term
disturbances
Since information about switching components in input current for mentioned studies is
very minor simplifications in modeling can be made
█ Simplified models linearization linearized models
averaging averaged models
Simplified models are created to keep information about LF bandwidth behaviour, i.e.
about LF conducted disturbances
█ Modeling in frequency domain
There are also models and procedures to obtain models for modeling of disturbing
loads in frequency domain
█ Fixed current sources based “equivalent” models
█ Norton “equivalent” models – cross-harmonic complex admittance models
-200
-150
-100
-50
0
50
100
150
200
-0.4 -0.2 0 0.2 0.4
Lamp current i L (A)
La
mp
vo
lta
ge
vL
(V
)
for
for
9
█ Modeling of FL at HF
ZSLF
CB
CF
RF
LR
CF
RL
-350
-250
-150
-50
50
150
250
350
0 5 10 15 20 25 30
Time (ms)
Lin
e v
olta
ge
an
d c
urr
en
t, .
DC
bu
s v
olta
ge
v (
V),
i/3
00
(A
), v
B (
V)
v B
i v
t TO
a)
-150
-100
-50
0
50
100
150
0 5 10 15 20 25 30
Time (ms)
La
mp
vo
lta
ge
an
d c
urr
en
t .
vL
(V
), i
L/3
00
(A
)
i L
v L
d)
-150
-100
-50
0
50
100
150
0 0.05 0.1 0.15Time (ms)
La
mp
volta
ge
an
d c
urr
en
t .
vL
(V
), i
L/3
00
(A
)
v L
i L
Based on dynamic AV characteristic curve of a discharge in
normal operation if supplied by HF current, a FL can be
substituted by a resistance
It is acceptable if DC voltage ripple (vB) is reasonable (up to
30%), otherwise different model has to be used to keep
correctness, for instance voltage driven resistance, etc.
Then model (switched model) of an EB can be drawn as
follows:
Experimental results: CFL of about 20 W, 230 V @ 50Hz
EMI Filter
Rectifier Inverter
Driver Ouput stage
230V ~
L
N CB
i
v vB
iI
iLvL
Basic EB for CFL
10
Frequency
0Hz 125KHz 250KHz 375KHz
I(R1)
1.0pA
1.0uA
1.0A
Waveforms of supply voltage (red), input current
(green) and of DC bus voltage (blue);
Spectra of input current: full and LF part,
THDI=146% (up to h=50)
N
R6
430
L4
2.3mH
D3
31
houtL
L2
2mH
1 2+
M2
IRF840
lamp_N
D6R8
10kC6
6.8u
C8
6.8n
lamp_L
V6TD = 0
TF = 0.5uPW = 9uPER = 20u
V1 = 0
TR = 0.5u
V2 = 10
D43
1
houtN
D2
31R1
0.4
R7
.05
R5
.05
C733n
D5
31
D7
0
V5TD = 10u
TF = 0.5uPW = 9uPER = 20u
V1 = 0
TR = 0.5u
V2 = 10
R9
10k
M1
IRF840
-
R10
6.8V4
FREQ = 50VAMPL = 325VOFF = 0
Frequency
0Hz 2.0KHz 4.0KHz
I(R1)
0A
40mA
80mA
120mA
Time
20ms 30ms 40ms 50ms 60ms
1 I(R1) 2 V(L)- V(N) V(+)- V(-)
-400mA
0A
400mA
-700mA
700mA1
>>
-400V
-200V
0V
200V
400V2
█ Simple switched model of a CFL with basic EB
Model in PSpice of a 18W CFL Simulation results
Switching models are only necessary when switching
ripples are of interest or detailed transient information is
needed
It slows down computing (switching frequency is
thousand times higher then system frequency) and
information about High Frequency (HF) ripple is useless
from point of view of Low-Frequency (LF) disturbances
propagation study
Basic EB for CFL
11
█ Simplification of the inverter stage
EMI Filter
Rectifier Inverter
Driver Ouput stage
230V ~
L
N CB
i
v vB
iI
iLvL
-350
-250
-150
-50
50
150
250
350
0 5 10 15 20 25 30
Time (ms)
Lin
e v
olta
ge
an
d c
urr
en
t, .
DC
bu
s v
olta
ge
v (
V),
i/3
00
(A
), v
B (
V)
v B
i v
t TO
a)
-0.2
-0.1
0
0.1
0.2
0.3
0.4
0 5 10 15 20 25 30
Time (ms)
Invert
er
curr
en
t
iI (A
), i
IF/4
(A
) i I
i IF
b)
Experimental results: CFL of about 20 W, 230 V
@ 50Hz
Switching frequency of inverter is constant in steady-state and
normal operation; the inverter control circuit does not contain
regulation of the lamp current
Then, for LF phenomena study purposes, the inverter with
output stage and lamp can be replaced by an equivalent linear
resistance of constant value (representing the same limitations
as in case of the lamp substitution). Switching signals of the
inverter are de facto averaged over the switching period.
Simplified model of the basic EB for CFL is as follows:
ZSLF
CB
CF
RF
REL
Basic EB for CFL
*) iIF is filtered current iI
IF
BEL
i
vtR )(
12
Time
560ms 570ms 580ms 590ms 600ms
1 I(R1) 2 V(L)- V(N) V(+)- V(-)
-500mA
0A
500mA
1
>>
-400V
0V
400V2
Frequency
0Hz 2.0KHz 4.0KHz
I(R1)
0A
40mA
80mA
120mA
D3
31
D23
1
R10
6.8
N
D5
31
C6
6.8u
0
V4
FREQ = 50VAMPL = 325VOFF = 0
L+
R6
5k
R1
0.4 D4
31
-
L2
2mH
█ Simplified model of the basic EB for CFL
Model in PSpice of a 18W CFL Simulation results
Waveforms of supply voltage (red), input current
(green) and of DC bus voltage (blue);
Spectra of input current: THDI=146% (up to h=50)
Simulation results in term of LF part of input current conform
with the results obtained for corresponding switching model
Basic EB for CFL
13
█ Basic EB for CFL performance analysis based on simplified model
Lser
CB
Rser
REL
ELBC RC
Scheme composed only of essential parts
Magnitude and shape of input / line currrent (i.e.
power and spectral components) are full given by
value of Rser, Lser, CB and REL and by their correlation
input power is mainly represented and thus
estimated by REL
line current waveform is matter of balance in
charging and discharging process over half
system period given by CB in relation to REL.
An invariant parameter describing the rectifier
load there is C – load/converter time constant:
serial combination of Lser and CB constitutes a
series resonant circuit influencing input current
by self-oscillations at resonant frequency fr. The
resonant frequency is second invariant
parameter of the rectifier.
Expression of fr comes from circuit series
impedance:
Thus fr is as follows:
the last one component there is Rser which
smooths line current and which can be
normalized by CB in form of series time constant
or by equivalent capacitive reactance at
fundamental frequency:
serBELBserB
rLCRCLC
f
2
111
2
122
22
221
1
1
ELB
ELB
ser
ELB
ELser
RC
RCLj
RC
RRZ
0.1
1
10
100
1000
10000
10 100 1000 10000f r (Hz)
|Z| ( W
)
L ser = 5H2H
1H0.5H
0.2H0.1H
50mH20mH
10mH
5mH2mH
1mH0.5mH
C B =10 mF
R EL =5150 W C =51.5 ms}
serBS RC serB
CB
serS RC
X
Rr 1
Basic EB for CFL
14
█ Basic EB for CFL performance analysis based on simplified model (cont.)
0
50
100
150
200
250
300
350
101001000 C (ms)
V B,avg
(V)THD I(I1) (%), h˂40I (mA)
THD I(I) (%), h˂40
DVB (%)
0
25
50
75
100
101001000 C (ms)( I
h/I
1.
100 (
%)
I 1 /I 1
I 3 /I 1
I 5 /I 1
I 7 /I 1 I 9 /I 1 I 11 /I 1 I 13 /I 1 I 15 /I 1
0
25
50
75
100
1 5 9
13
17
21
25
29
33
37h (-)
( Ih/I
1).
100 (
%)
C =10 ms
26 ms
258 ms
103 ms
52 ms
1030 ms 515 ms
Influence of C
To comply with harmonic current emission limits
and to maintain reasonable DC voltage ripple, the
C of CFLs is in range (10)-15-50-(70) ms
The larger C the shorter conduction time of the
rectifier and higher content of harmonics in input
current
Simulation results for various C while Rser=0 W,
Lser=0 H:
Relative amplitude spectrum of line current for various
load/converter time constants
Relative amplitudes of chosen harmonics vs. load/
converter time constant
Chosen circuit quantities vs. load/ converter time
constant
Basic EB for CFL
15
█ Basic EB for CFL performance analysis based on
simplified model (cont.)
10
100
1000
10100100010000 f r (Hz)
V B,avg (V)
THD I(I) (%), h <40
THD I(I1) (%), h <40
D V B (%)
0
25
50
75
100
10100100010000 f r (Hz)
( Ih/I
1).
100 (
%) I 1
I 3
I 5
I 7
I 9
I 11
I 15
I 13
0
25
50
75
100
1 5 9
13
17
21
25
29
33
37h (-)
( Ih/I
1).
100 (
%)
fr=712 Hz 503 Hz 356 Hz
225 Hz 113 Hz 36 Hz
16 kHz
Hz
2251 Hz
1592 Hz
1125 Hz
Influence of fr
Inductance Lser is composed of three parts representing: a
choke in ac or dc part of rectifier “smoothing and improving“
current shape, inductance of an EMI filter, if there are
employed; and effective inductance of supply network. The fr
can be practically in range from 17 kHz to 400 Hz
With decreasing resonance frequency the self-oscillation
wave frequency is traveling to lower harmonic order while
multi conduction of the input current in each half-period can
occur
Simulation results for various fr , for Rser=0 W and C=51.5
ms:
Basic EB for CFL
Frequency
0Hz 0.5KHz 1.0KHz 1.5KHz 2.0KHz 2.5KHz 3.0KHz
1 I(R2)
0A
40mA
80mA
120mA1
2
>>
16
█ Basic EB for CFL performance analysis based on simplified model (cont.)
█ Analytical solution
C=51.5 ms , fr=1592 Hz, S=7.5 ms
Rser=7.5 W, Lser=1 mH, CB=10 mF, REL=5150 W (blue)
Rser=0.75 W, Lser=0.1 mH, CB=100 mF, REL=515 W (green)
Influence of S
Summary
Resistance Rser consists of series combination of the supply network effective resistance, used chokes
resistances and resistance of a resistor applied in input side of EB to limit inrush current (~ Ohms).
The Rser attenuates line current shape and possible resonant oscillations in the current and S can be
practically in range from 0.2 ms to 0.2 ms
The input current waveform is invariant if the rectifier invariant parameters C, fr and S are of the same
value
En example (simulation results):
Frequency
0Hz 0.5KHz 1.0KHz 1.5KHz 2.0KHz 2.5KHz 3.0KHz
I(R2)
0A
0.4A
0.8A
1.2A
Except numerical simulation, the resulting input current waveform can be obtained from solution of
analytical description of the simplified model. The most critical part of it there is to find out conduction
angles bounding CB capacitor charging and discharging areas, especially in case of multi-conduction
Time
1.480s 1.485s 1.490s 1.495s
I(R2)
-10A
0A
10A
Basic EB for CFL
17
EB with passive PFC
█ Division of the passive PFCs (patterns)
Passive PFC techniques
- inductive passive PFC
CB
v
iig
iI
vB
LF,DCLF,AC
C VF2
v
iig
vB
C VF1
D VF1
D VF2
D VF3
- capacitive passive PFC – Valley-Fill - other variants of the Valley-Fill
C VF2
v
iig
iI
vB
LVF
C VF1
D VF1
D VF2
D VF3
RVF
C VF2
v
iig
iI
vB
C VF1
D VF1
D VF2
D VF3
C VF3D VF4
D VF5
D VF6
i
v
iI
vB
CVF1
CVF2
CpL
CpH
RVF2
RVF1
RpH
RpL
18
Double-stage active PFC EB
█ Typical circuit of double-stage active PFC EB
Active boost type PFC, in dependences on employed regulation
loops, emulates EB input to be like a resistor and regulates output
voltage (vB) on reference, i.e. on constant output power, thus whole
the inverter part including lamp can, for modeling, substituted by
resistance again, if interested in the line current
The PFC can work in Discontinues- Continuous- or Critical
Conduction Mode (DCM, CCM, CrCM) with corresponding (various)
switching control strategies, for example:
PWM
CB
LBT
iT
iDig
vg
2xLHF
2xCHF230V ~
L
N
i
v
Controller PFC circuit
iI
iLvL
vB
Measurement results
19
Double-stage active PFC EB
█ Switching model of an active PFC for EB
D102DN4722
RlowM18k
X1
MTP8N50
cmp
drain
RsL
162m
C1
22n
Rzcd
22k
Rupp1.59Meg
L HV
Rs
13m
RuppM
2.2Meg
Cin330nF
Ccmp0.68uF
Rsense2.5
Rlow
10k
cs
-
+
MC33262
FB
CMP
MUL
CS ZCD
GND
DRV
VCC
U1 MC33262
R1
0.0001
Dout
MUR130
U2
XFMR10.04692
0 1
2 3
CMUL
10nF
L1
1mH Rstart
100k
Resr70m
0
CVcc
100uF
mul
Vinput
FREQ = 50VAMPL = 325VOFF = 0
Rload
4444
D101DN4722
D100DN4722
Lp
1.1mH
Cout40uF
C2
100n
DN4722D103
D1
DN4934
drvL2
1mH
N
Model in PSpice Simulation results
Waveforms of supply voltage (blue), input current
(green) and of DC bus voltage (red);
Spectra of input current: THDI=5.1 % (up to h=50)
Model represents full controlling with CrCM control strategy, it
means switching frequency is changing within period
Again, computing is very time consuming
Content of LF harmonics is very small (THDI practically up to
15%). On other hand PFC causes different time variations in
input current when supply voltage magnitude is varying (in
depencance on regulation scheme) 0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
3 9
15
21
27
33
39h (-)
(IhI1
).100 (
%)
.
20
Double-stage active PFC EB
█ D-S Active PFC EB response to voltage changes
Simulations using switching models are extremely time consuming.
The solution is to apply an averaging technique to obtain an Averaged-switch model
Averaged switch modeling allow us to predict steady-state characteristics and Low-bandwidth
dynamics of converters
Measurement results
-400
-200
0
200
400
0 50 100 150 200 250 300Time, t (ms)
Su
pp
ly v
olta
ge
, v (
V)
-2
-1
0
1
2
Lin
e c
urr
en
t i,
I (
A)
v i I(RMS1/2p)
Voltage dip to from 230 to 90 V, duration time of 150 ms
21
Double-stage active PFC EB
█ Averaged model of the boost rectifier circuit
Signals are averaged over switching period. Average models change the
discontinuous system into the continuous system
Substitute for switch-diode combination of the boost DC/DC conv. suitable
for both the DCM and CCM with fixed switching frequency fs and variable
duty cycle ratio d:
Boost rectifier becomes ideal, assuming
that inner wide/bandwidth current
controlling loop operates ideally
High-frequency switching components
removed by averaging
Line current low-frequency components
remain
Resulting model in nonlinear and time-
varying
Switch network
DCM;
2
CCM;
2
12
2
v
ifLd
d
d
u
SBT
2
12
2
2
,
v
ifLd
ddMAXu
SBT
CCM/DCM boundary:
22
Frequency
0Hz 0.25KHz 0.50KHz 0.75KHz
I(R0)
0A
100mA
200mA
300mA
Time
0.980s 0.985s 0.990s 0.995s
1 V(L)- V(N) V(+)- V(-) 2 I(R0)
-500V
0V
500V1
-400mA
0A
400mA2
>>
Time
0.980s 0.985s 0.990s 0.995s
1 V(L)- V(N) V(+)- V(-) 2 I(R0)
-500V
0V
500V1
-400mA
0A
400mA2
>>
Frequency
0Hz 0.25KHz 0.50KHz 0.75KHz
I(R0)
0A
100mA
200mA
300mA
Double-stage active PFC EB
█ Averaged model of the boost rectifier circuit (cont.)
Model in PSpice Simulation results
Waveforms of supply voltage (green), input current (blue) and
of DC bus voltage (red); Spectra of input current: THDI=27.3 %
(up to h=50)
Waveforms of supply voltage (green) distorted by 3rd and 5th
harm. (10%-0°; 5%-180°), input current (blue) and of DC bus
voltage (red); Spectra of input current: THDI=17.6 % (up to
h=50)
Controlling loop cover Low-bandwidth DC
voltage loop only. A part correcting d based on
input voltage waveform is not employed. Thus
line current distortion is bigger than in case of
full voltage loop implementation
The first order PI controller integral time constant
is about 20 ms, it means that cut-off frequency of
corresponding transfer function is at approx. 8
Hz
23
Time
400ms 450ms 500ms 550ms 600ms 650ms 700ms 750ms 800ms
1 V(L)- V(N) V(+)- V(-) 2 I(R0)
-500V
0V
500V1
-1.0A
0A
1.0A2
>>
Time
400ms 450ms 500ms 550ms 600ms 650ms 700ms 750ms 800ms
1 V(L)- V(N) V(+)- V(-) 2 I(R0)
-500V
0V
500V1
0A
2.0A
4.0A
6.0A2
>>
Double-stage active PFC EB
█ Averaged model of the boost rectifier circuit (cont.)
Simulation results Response of the model on slow and rapid
supply voltage changes:
a) voltage step from 230 to 115 V (sinusoidal
waveform)
b) voltage dip from 230 to 115 V for 100 ms
(sinusoidal waveform)
Waveforms of supply voltage (green), input current (blue) and
of DC bus voltage (red);
24
Single-stage active PFC EB
█ Typical circuit of Single-Stage (S-S) active PFC EB
In order to reduce production costs, Single-Stage
topologies were introduced. S-S topology is able to
provide some of D-S functionalities: input “emulates”
resistor and feeding of lamp is ensured, EB does not
regulate DC bus voltage and so lamp voltage (current)
Some of characteristics:
-switching frequency is fixed in steady-state (normal
operation)
- typically w/o regulation loops
- DC bus voltage is of natural behavior depending on
employed circuit which can lead to:
- up to double of standard DC voltage level or
- serious DC bus voltage variation causing periodical
drift of lamp operating point, it means modeling of
lamp by a resistance could be inaccurate
Some of other variants
LBT
CB
Lr
Cr
DBT
S1
S2
2xLHF
2xCHF230V ~
L
N
i
v
iLvL
ig
vB
CB
Lr
Cr
Cin
Lin
Dx Dy
S1
S2
CB
Lr
Cr
Cin1
Cin2
Lin
S1
S2
LBT
CB
Lr
Cr
Cin1
Cin2
DBT2
DBT1
S1
S2
Measurement results
25
Single-stage active PFC EB
█ Switching model of an S-S active PFC for EB
Model in PSpice
M2
IRF840
houtN
D3
31
V5TD = 10u
TF = 0.5uPW = 9uPER = 20u
V1 = 0
TR = 0.5u
V2 = 10
lamp_N
D4
31
N
C4
100n
D7
MUR160
-
R7
.05
R1
0.0001
D23
1
D6
MUR160
R910k
R6
304
C733n
L
D8
MUR160
R8
10k
D5
31
+ R5 .05
V4
FREQ = 50VAMPL = 325VOFF = 0
L3
5.0mH
R100.0001
C5
100nlamp_L
L4 3.8mH
houtL
M1
IRF840
C8
6.8n
C6
35u
0
V6TD = 0
TF = 0.5uPW = 9uPER = 20u
V1 = 0
TR = 0.5u
V2 = 10
L2
5mH
1 2
Simulation results
Time
80ms 90ms 100ms 110ms 120ms
1 I(R1) 2 V(L)- V(N) V(+)- V(-)
-400mA
0A
400mA1
-0.5KV
0V
0.5KV
1.0KV2
>>
Frequency
0Hz 50KHz 100KHz
I(R1)
10uA
1.0A
1.0nA
0.0
2.0
4.0
6.0
8.0
3 7
11
15
19
23h (-)
(IhI1
).100 (
%)
.
Waveforms of supply voltage (red), input current
(green) and of DC bus voltage (blue);
Spectra of input current: THDI=7.9 % (up to h=50)
Model represents S-S interleaved PCF EB
The model can be again simplified using averaging
technique if just LF phenomena are subject of interest.
Simplification procedure to get averaged-switch model, as in
case of D-S active PFC EB can be adopted. In fact the
included PFC operate with constant switching frequency and
even duty ratio.
26
█ Modeling of LEDs
LEDs (lamps) can be simply modeled using diode model(s)
of appropriate parameters
In a case of stable lamp voltage (current) with small ripple
ensured by feeding converter, a resistance can be
employed as substitute
Experimental results: Screw/based LED lamp
of about 6 W, 230 V @ 50Hz
Basic Driver for LEDs
L
NvB
CB
i
viI
iL
vL
Cr
Lr1 Lr2-350
-250
-150
-50
50
150
250
350
0 5 10 15 20 25 30Time (ms)
Lin
e v
olta
ge
an
d c
urr
en
t, .
DC
bu
s v
olta
ge
,
v (
V),
i (
mA
), v
B (
V)
vi
v B
0
20
40
60
80
100
120
140
160
0 5 10 15 20 25 30
Time (ms)
La
mp
vo
lta
ge
an
d c
urr
en
t, .
vL (
V),
iL(m
A)
i L
v L
0
10
20
30
40
50
60
0 5 10 15 20 25 30
Time (ms)
Invert
er
curr
en
t,
iI (m
A),
iIF
(m
A)
i I
i IF
0
2
4
6
8
10
0 5 10 15 20 25 30
Time (ms)
Eq
uiv
ale
nt D
C b
us .
loa
d, R
EL (
kW
)
27
█ Modeling of drivers with LEDs
There is pretty symmetry between LED drivers and EB in modeling:
If the switching converter is of fixed switching frequency and operating with constant
duty ratio, whole the second stage of the converter with the LEDs string can be, using
averaging method, replaced by an equivalent resistance which loads rectifier as in
case of EB. Then following model can be used:
In a case the driver second stage include controlled switching converter, its averaged
switch model can be utilized, following already described procedure. The same can be
applied for modeling of an active PFC if it is present.
Basic Driver for LEDs
ZSLF
CB
CF
RF
REL
28
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