IRS2168D Additional Design Information

Application Note AN-1151
IRS2168D Additional Design Information
By T. Ribarich
Table of Contents
Page
Introduction .................................................................................................. 1
Ballast Oscillator …………………………...................................................... 2
PFC Circuit ………………..………................................................................ 4
Resonant Tank Output Circuit …………………………………………………. 9
IC Start-Up and Supply Circuit .................................................................... 14
High-Side VBS Bootstrap Supply ............................................................... 17
PCB Layout Guidelines ............................................................................... 19
Conclusion ................................................................................................... 21
Introduction
Designing a fully-functional ballast using the IRS2168D can be a challenging
task. Much care should be taken when generating the ballast circuit schematic,
selecting component values and ratings, and generating the ballast PCB layout.
The purpose of this application note is to provide additional information to help
decrease design time and avoid circuit problems due to wrong component values
or ratings, incorrect programming of IC parameters, and noise. This application
note includes helpful information for programming the ballast oscillator frequency,
calculating the PFC inductor value, designing the resonant tank output circuit,
and designing the start-up and low- and high-side supply circuitry. Layout
guidelines are also included to help avoid noise problems that can cause circuit
malfunction or poor ballast performance.
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Ballast Oscillator Frequency
The IC oscillator includes an internal CT timing capacitor and an external
timing resistor at the RFMIN pin. The frequency is programmed with the RFMIN
resistor connected between pin 4 and COM, and, the RPH resistor connected
between pin 3 and pin 4 (Figure 1). An internal 2V reference at the RFMIN pin,
together with the external RFMIN resistor, sets up a current flowing out of the
RFMIN pin. This current is then mirrored internally and used to charge and
discharge the internal CT timing capacitor between two fixed thresholds. By
increasing RFMIN, the current will decrease, the CT capacitor will charge and
discharge slower and the frequency will decrease. Inversely, by decreasing
RFMIN, the current will increase, the CT capacitor will charge and discharge
faster and the frequency will increase.
Figure 1, IRS2168D ballast oscillator circuit.
The RFMIN resistor sets the minimum operating frequency of the ballast
half-bridge gate drivers (LO and HO) during RUN mode. During PREHEAT
mode, the VCO pin is connected to COM so that the higher preheat frequency is
programmed with the parallel combination of resistors RFMIN and RPH. The
equivalent RFMIN resistance versus frequency graph (Figures 2a and 2b) can be
used to select the correct RFMIN and RPH values for the desired preheat and
running frequencies. It is recommended that the minimum equivalent RFMIN
resistance should be no less than 10K ohm (see IRS2168D Datasheet, page 3).
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180
Frequency (KHz)
160
140
120
100
80
60
40
20
10
15
20
25
30
35
40
45
50
Equivalent RFMIN (Kohms)
Figure 2a, Equivalent RFMIN vs. Frequency (RFMIN=10K to 50K)
40
Frequency [kHz]
35
30
25
20
15
10
5
0
50
75
100
125
150 175 200
RFMIN [Kohms]
225
250
275
300
Figure 2b, Equivalent RFMIN vs. Frequency (RFMIN=50K to 300K).
The frequency sweep time (also known as the ignition ramp time) is then
programmed with an external CVCO capacitor between the VCO pin and COM.
When the VCO pin is disconnected from COM at the end of PREHEAT mode, the
voltage at the bottom of the RPH resistor charges up to the 2V level at the
RFMIN pin at a time constant given by RPH and CVCO. This causes the total
resistance at the RFMIN pin to increase as well and results in a smooth transition
of the frequency from the preheat frequency down to the final running frequency.
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PFC Inductor Calculations
The IRS2168D includes a boost-type PFC controller that operates in
critical-conduction mode. During the PFC MOSFET on-time, the inductor current
ramps up linearly to a peak current value (Figure 3) depending on the
instantaneous value of the rectified AC line voltage, the inductor value and the
on-time. During the PFC MOSFET off-time, the inductor current discharges back
down linearly to zero and the PFC switch is turned on again.
Figure 3, Boost-type converter and inductor current during critical-conduction
mode.
The result is a triangular shaped current that varies in frequency
depending on the level of the instantaneous rectified AC line voltage (Figure 4).
The maximum switching frequency occurs at the zero-crossings of the rectified
AC line voltage and the minimum switching frequency occurs at the peak of the
rectified AC line voltage.
V, I
t
Figure 4, PFC inductor current amplitude and frequency during the AC line
voltage cycle.
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To calculate the inductor value as a function of the desired minimum
switching frequency, the following derivation can be used:
Definition of terms:
VBUS
VAC NOM PK
η
= DC bus voltage
= Peak voltage at nominal AC input condition
(VAC NOM PK = VAC RMS ⋅ 2 )
= Boost converter efficiency (typically 0.95)
f MIN
POUT
= Minimum switching frequency occurring at the peak of the AC input voltage
I PFC
I PFCMAX
t ON
= Peak inductor current occurring at the peak of the nominal AC input voltage
t OFF
LPFC
= PFC off-time
= Ballast output power
= Maximum peak inductor current occurring at the peak of the minimum AC input voltage
= PFC on-time
= PFC inductor
During the on-time of the PFC MOSFET, the inductor is connected
between the rectified AC input voltage and ground and the following equation
applies:
VAC NOM PK = LPFC ⋅
I PFC
t ON
⇒
t ON =
LPFC ⋅ I PFC
VAC NOM PK
[Sec]
[1]
During the off-time of the PFC MOSFET, the inductor is connected
between the rectified AC input voltage and a diode drop above the DC bus and
the following equation applies:
VBUS − VAC NOM PK = LPFC ⋅
I PFC
t OFF
⇒
t OFF =
LPFC ⋅ I PFC
VBUS − VAC NOM PK
[Sec]
[2]
Combining the on-time and off-time equations to solve for frequency gives
the following equation:
f MIN =
t ON
VAC NOM PK ⋅ (VBUS − VAC NOM PK )
1
=
+ t OFF
LPFC ⋅ I PFC ⋅ VBUS
[Hz]
[3]
To solve for the peak inductor current, the following relationship between
the input power and output power is used (assuming PF=1):
Pin ⋅ η = VAC NOM RMS ⋅ IAC NOM RMS ⋅ η = POUT
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⇒
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IAC NOM RMS =
POUT
VAC NOM RMS ⋅ η
[4]
5/21
For a triangular shaped waveform, the peak value is equal to 2 2 times
the r.m.s. value. Applying this ratio to the r.m.s. input current gives the following
result for the peak PFC inductor current at the nominal AC line input voltage:
4 ⋅ POUT
POUT ⋅ 2 ⋅ 2
P ⋅2⋅ 2
= OUT
=
[Apk] [5]
VAC NOM RMS ⋅ η VAC NOM PK
VAC NOM PK ⋅ η
⋅η
2
The maximum peak inductor current occurs at the peak voltage during
minimum AC line input conditions and is calculated as:
I PFC = IAC NOM RMS ⋅ 2 ⋅ 2 =
I PFCMAX =
4 ⋅ POUT
VAC MIN PK ⋅ η
[Apk]
[6]
The maximum peak inductor cycle-by-cycle current limit is programmed at
the OC pin of the IRS2168D with the PFC current sensing resistor, ROC, and an
internal 1.25V threshold and is calculated with the following equation:
ROC =
1.25
[Ohms]
I PFCMAX
[7]
Substituting the peak inductor current result from equation [5] into the
frequency equation [3] gives the following result:
f MIN =
2
VAC NOM
(VBUS − VAC NOM PK ) ⋅ η
PK
4 ⋅ LPFC ⋅ POUT ⋅ VBUS
[Hz]
[8]
[H]
[9]
Solving for the PFC inductor gives the following result:
LPFC =
2
VAC NOM
(VBUS − VAC NOM PK ) ⋅ η
PK
4 ⋅ f MIN ⋅ POUT ⋅ VBUS
If the PFC inductor value is known then equation [8] can be used to
calculate the minimum PFC switching frequency that occurs at the peak of the
rectified AC input voltage. If the desired minimum switching frequency is known
then equation [9] can be used to calculate the PFC inductor value but this should
be checked carefully with the following additional calculations to make sure that
the on-time modulation circuit is working properly so that low THD is achieved.
The IRS2168D PFC control circuit includes an additional on-time
modulation circuit for achieving low THD. The on-time modulation circuit
increases the on-time as the off-time decreases near the zero-crossing regions of
the AC line input. This is necessary to reduce cross-over distortion of the AC line
current and therefore reduce THD. To ensure that the on-time modulation circuit
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is working properly, the PFC inductor value must be selected such that the PFC
off-time at the peak of the AC line, at the nominal AC line input voltage, is slightly
higher than the off-time where the on-time modulation begins working. The ontime modulation begins working at an off-time of about 7usec (Figure 5). So
selecting an off-time of 8usec will ensure that the on-time modulation is not
working at the peak of the AC line voltage and that it is working when the rectified
AC line voltage is lower near the AC line zero-crossings.
PFC On-Time Modulation Curve
(On-Time vs. Off-Time)
20
On-Time [usec]
18
16
14
12
10
8
0
2
4
6
8
10
Off-Time [usec]
Figure 5, PFC on-time vs. off-time curve for on-time modulation (VCOMP=10V).
Using this off-time requirement of 8usec at the peak of the rectified AC line
voltage during nominal AC line voltage conditions, we can derive the following
equation to determine the best value for the PFC inductor to ensure that the ontime modulation is working correctly:
VBUS − VAC NOM PK = LPFC ⋅
i PK
t OFF
⇒
LPFC =
(VBUS − VAC NOM PK ) ⋅ t OFF
I PK
[10]
Substituting the peak inductor current equation [5] into equation [10] gives:
LPFC =
(VBUS − VAC NOM PK ) ⋅ t OFF ⋅ VAC NOM PK ⋅ η
4 ⋅ POUT
[11]
Inserting the off-time requirement of 8usec for toff into equation [11] gives
the final equation for calculating the correct PFC inductor value:
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LPFC =
(0.000008) ⋅ (VBUS − VAC NOM PK ) ⋅ VAC NOM PK ⋅ η
4 ⋅ POUT
[H]
[12]
If the off-time at the peak of the rectified AC input voltage is set too high
above 8usec, then the on-time modulation may not be increasing the on-time
enough (or not at all) at the AC line zero-crossings and will result in the THD
being too high. If the off-time at the peak of the rectified AC input voltage is set
too low below 8usec, then the on-time modulation will be working the entire time
causing distortion of the AC input current and will also result in the THD being too
high. Therefore, equation [12] should be used to calculate the PFC inductor value
and equation [8] can be used to then calculate the resulting minimum switching
frequency occurring at the peak of the rectified AC line voltage. If equation [9] is
used to determine the PFC inductor value based on the desired minimum
switching frequency, then equation [2] should be used to check the resulting offtime at the peak of the rectified AC input voltage to make sure it is approximately
8usec. This will ensure that the on-time modulation is working correctly and will
result in low THD of the AC line input current.
The PFC control loop speed must be properly set so that the shape of the
AC line input current follows the shape of the AC line input voltage. This is
necessary so that the electronic ballast appears as a “resistive” load to the AC
line. Since the AC line input voltage is changing very slowly (50/60Hz), the PFC
loop speed should also be set very low so that the current can follow the shape
of the voltage properly. The better the current follows the shape of the voltage,
then the lower the resulting harmonic distortion of the current (THD). If the loop
speed is set too fast, then distortion of the current will occur and cause high
harmonic distortion. If the loop speed is set too slow, then a poor transient
response can result and cause large voltage over-shoot and/or under-shoot on
the DC bus during load changes. During preheat and ignition modes, the
operational transconductance amplifier (OTA) of the PFC circuit includes a high
gain mode to increase the loop speed to prevent large transients during lamp
ignition. During run mode, the OTA gain is then reduced so that the current
follows the voltage for high power factor and low harmonics. The PFC loop speed
is set using the external capacitor at the COMP pin (CCOMP) using the gm of the
OTA and the desired loop speed bandwidth. Using a typical gm of 100 umhos
for the OTA and a loop speed bandwidth of 20Hz, capacitor CCOMP is
calculated using the following equation:
C COMP =
gm
100
=
= 0.796 ⇒ 0.82
2 ⋅ π ⋅ BW 2 ⋅ π ⋅ 20
[uF]
[13]
Since the PFC loop speed is only a function of the OTA transconductance
and the desired bandwidth, this calculated value for CCOMP should remain fixed
for all ballast designs.
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Resonant Tank Output Circuit
The half-bridge inverter and resonant tank output circuit of the ballast
(Figure 6) perform the necessary functions to drive the fluorescent lamp. The
circuit includes a half-bridge switching circuit (MHS, MLS), a resonant inductor
(LRES:A), a resonant capacitor (CRES), a dc blocking capacitor (CDC), the
lamp, and voltage-mode filament heating circuits (LRES:B, CH1, LRES:C, CH2).
The functions performed by this circuit include preheating the lamp filaments,
igniting the lamp, and supplying a high-frequency AC current through the lamp
during running. All of these functions can be achieved by properly selecting the
resonant inductor and capacitor, and then controlling the frequency of the
inverter stage to preheat, ignite and run the lamp. The output resonant circuit is a
high-Q, series L-C circuit during preheat and prior to lamp ignition, and then
becomes a low-Q, series L, parallel R-C after ignition and during running.
Figure 6, Half-bridge and resonant tank output circuit.
The frequency of the half-bridge inverter driving the resonant tank
operates at a higher frequency (above the resonance frequency of the series L-C
circuit) during preheat mode. The frequency remains at the preheat frequency for
the duration of the preheat time (Figure 7) such that the lamp filaments are
heated to their correct emission temperature. The filament heating is achieved
with secondary windings from the inductor (LRES:B, LRES:C) and capacitors to
limit the heating current (CH1, CH2). After the preheat time has ended, the
frequency then sweeps down smoothly through the resonance frequency during
ignition mode (Figure 7). This causes the gain across the resonant tank circuit to
increase smoothly, as well as the voltage across the lamp, until the lamp ignition
threshold voltage is reached. The lamp then ignites and the frequency continues
to sweep down to the final run frequency where the gain of the resonant tank
circuit sets the correct lamp current (Figure 7). Different lamp types have different
preheat, ignition and running requirements. The resonant inductor (LRES) and
capacitor (CRES) values, together with the inverter operating frequencies, must
be selected carefully in order to satisfy each set of lamp requirements.
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Figure 7, Lamp output voltage timing diagram during preheat, ignition and run
modes.
To select the resonant tank component values and operating frequencies
the following procedure and equations can be used:
Definition of terms:
V BUS
= DC bus voltage
VLAMP
f RUN
PLAMP
RLAMP
LRES
C RES
VPH
f PH
V IGN
f IGN
I IGN
= Nominal r.m.s. lamp voltage during running conditions
= Operating frequency during lamp running conditions
= Nominal lamp power during running
= Equivalent lamp resistance during running
= Resonant tank inductor
= Resonant tank capacitor
= Peak output voltage across lamp during preheat mode
= Operating frequency during preheat mode
= Maximum peak output voltage across lamp during ignition mode
= Operating frequency occurring during maximum peak ignition voltage
= Maximum peak inductor current during maximum peak ignition voltage
The resonant inductor value is primarily used to set the lamp current
during running conditions at the desired running frequency. During run mode, the
running frequency can be calculated as a function of the resonant inductor with
the following equation:
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2
 2VBUS 


2 1− 

V
π
2


1
1
1
1
1
 LAMP 
− 2
+ 
− 2
−
f RUN =
2
2 
2
2π LRESCRES 2RLAMP
CRES
L2RESCRES
 LRESCRES 2RLAMPCRES 
[Hz]
[14]
[H]
[15]
[Ohms]
[16]
Solving for the resonant inductor gives the following result:
2
2 
 2
  2VBUS  
4 (2πf RUN)

2CRES(2πf RUN) + 4CRES(2πf RUN) − 4CRES(2πf RUN) + 2
1−


R
V
2
π
LAMP 

  LAMP  
2
LRES =
4
2
 2

4 (2πf RUN)
2CRES(2πf RUN) + 2

RLAMP 

Where,
RLAMP
2
VLAMP
=
PLAMP
During preheat mode, the frequency should be selected such that the
resulting lamp voltage is low. A low lamp voltage will prevent the lamp from
igniting too early during the preheat mode before the filaments are properly
heated which can cause end-blackening of the lamp and shorten the lamp
lifetime. During preheat mode, the preheat frequency as a function of the peak
output voltage across the lamp can be calculated with the following equation:
f PH =
1
2π
2VBUS
VPH π
LRES C RES
1+
[Hz]
[17]
During ignition mode, the frequency will ramp down from the preheat
frequency to the run frequency at a sweep rate programmed by CVCO of the
IRS2168D. As the frequency ramps down, the voltage across the lamp will
increase as the frequency decreases towards the resonance frequency. When
the voltage reaches the maximum peak output voltage, VIGN, as programmed by
the CS pin of the IRS2168D, the ignition regulation circuit will control the
frequency to keep VIGN constant during the ignition mode. The frequency
occurring during the ignition regulation at VIGN can be calculated with the
following equation:
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f IGN =
1
2π
2VBUS
VIGNπ
LRES CRES
1+
[18]
[Hz]
The peak inductor current flowing in LRES during the moment when the
maximum peak ignition voltage occurs during the ignition mode is calculated with
the following equation:
I IGN = f IGN C RESVIGN 2π
[Apk]
[19]
The inductor should be designed such that the maximum peak ignition
current can be reached without saturation occurring over temperature and
tolerances.
To program the DC bus voltage, preheat and run frequencies, and the
maximum ignition voltage, the external components around the IRS2168D must
be correctly selected. The DC bus voltage is programmed at the VBUS pin using
resistors RVBUS1, RVBUS2 and RVBUS (see Figure 10). Assuming RVBUS1
and RVBUS2 to be fixed, RVBUS is calculated using the following equation:
RVBUS =
4(RVBUS 1 + RVBUS 2 )
VBUS − 4
[Apk]
[20]
The run frequency is programmed at the FMIN pin with resistor RFMIN.
The value of RFMIN can be selected using the graphs in Figure 2.
The preheat frequency is programmed with the parallel combination of
resistor RPH and RFMIN. Use the graphs in Figure 2 to select the REQUIV value
for the desired preheat frequency, and then calculate RPH using the following
equation:
RPH =
RFMIN ⋅ REQUIV
RFMIN − REQUIV
[Apk]
[21]
The maximum peak ignition voltage is programmed at the CS pin with the
current sensing resistor, RCS, and an internal 1.25V threshold and can be
calculated using the following equation:
RCS =
1.25
I IGN
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[Apk]
AN-1151
[22]
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A typical design example is shown for a T5/54W lamp. The ballast and
lamp data is given as the following:
VACRMS
VACMIN
VBUS
PLAMP
VLAMP
CRES
fRUN
VPH
VIGN
RVBUS1,2
=
=
=
=
=
=
=
=
=
=
220VAC
185VAC
410VDC
54W
152VAC
3.3nF
40kHz
300Vpk
1000Vpk
680kOhms
The lamp data is used together with the design equations to calculate the
resonant tank circuit component values, operating frequencies, peak inductor
current, and IRS2168D ballast programming component values (Table I). The
PFC inductor value, PFC inductor peak current, PFC minimum switching
frequency, and the PFC current sensing resistor value have been calculated as
well.
Parameter
Calculated Value
Units
Equation Used
RLAMP
428
Ohms
[16]
LRES
1.7
mH
[15]
fPH
84.7
kHz
[17]
fIGN
69.6
kHz
[18]
IIGN
1.4
Apk
[19]
RVBUS
13.4
kOhms
[20]
RFMIN
45.0
kOhms
Graph, Fig.2
RPH
43.0
kOhms
Graph, Fig.2, [21]
RCS
0.9
Ohms
[22]
LPFC
1.1
mH
[12]
IPFCMAX
0.87
Apk
[6]
fMIN
94.8
kHz
[8]
ROC
1.4
Ohms
[7]
CCOMP
0.82
uF
[13]
Table I, Calculated resonant tank and PFC circuit parameter values.
When comparing the calculated values versus actual bench
measurements, differences can occur due to lamp tolerances, component
tolerances, DC bus tolerances and component power losses.
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IC Start-Up and Supply Circuitry
The external IC supply circuit is designed to perform four main functions.
The first function is to supply the micro-power current to VCC during UVLO and
Fault modes. The second function is to set the AC line input voltage turn-on
threshold for the complete ballast. The third function is to supply the necessary
ICC current to VCC during normal Preheat, Ignition and Running modes. The
fourth function is to supply the IBS current to the VBS high-side supply. The first
and second functions are performed by the supply resistor, RSUPPLY,
connected between the rectified AC line input and VCC (Figure 8). This resistor
supplies the necessary micro-power current to VCC during UVLO and Fault
modes.
Rectifier (+)
DC Bus (+)
RSUPPLY
HO
RHO
MHS
16
VS
15
To Load
CBS
VB
BSFET
CSNUB
14
VCC
R2
R1
CVCC1
CVCC2
13
BSFET
CONTROL
COM
12
LO
DCP1
RLO
11
MLS
DCP2
CS
R3
10
CCS
RCS
DC Bus (-)
Load Return
Figure 8, IC start-up and supply circuitry.
During UVLO mode, this resistor determines the AC line turn-on voltage
for the IC by supplying the correct amount of current such that VCC reaches the
VCCUV+ threshold at the desired AC line voltage. The IRS2168D datasheet lists
the nominal IQCCUV current to be 220uA at VCC=8V (IRS2168D datasheet,
page 3). To calculate the correct value for the RSUPPLY resistor, the nominal
IQCCUV current value just prior to VCC reaching VCCUV+ should be used
instead. VCCUV+ minus 100mV is defined as the VCC voltage level just before
turn-on. By measuring several ICs on the bench, this current has been
determined to be approximately 300uA. The RCPH resistor connected between
VCC and the CPH pin needs to be considered as well. During UVLO mode the
CPH pin is connected to COM so there is current flowing from VCC through
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RCPH to COM as well. The value for RSUPPLY can therefore be calculated
using the following equation:
RSUPPLY ≅
R SUPPLY ≅
VACON PK
((VCCUV + ) − 100mV )
I QCCUV @(VCCUV + )−100 mV +
RCPH
VAC ON PK
((VCCUV + ) − 100mV )
0.000300 +
RCPH
[Ohms]
[23]
[Ohms]
[24]
Any additional current being supplied from VCC to the external ballast
circuitry needs to be included in this calculation as well. So the 300uA value plus
the additional current flowing through RCPH may need to be increased
depending on what additional circuits (pull-up resistors, filament detection
circuits, etc.) are connected to VCC.
The maximum power loss for RSUPPLY occurs when the AC line input
voltage is at the maximum value of the specified input voltage range. With
RSUPPLY between the output of the full-wave bridge rectifier and VCC, the
power loss in resistor RSUPPLY is calculated as:
PRSUPPLY ≅
(VAC MAX RMS − VCC ) 2
[Watts]
RSUPPLY
[25]
The power loss and resulting temperature of RSUPPLY should be
measured on the bench under high AC line conditions to make sure the power
rating of RSUPPLY is correct. If necessary, two resistors can be placed in series
for RSUPPLY to divide the power loss, reduce the temperature and to reduce the
maximum voltage drop across each resistor.
The third function is performed by the charge pump supply circuit
connected to the half-bridge switching node, VS (Figure 8). After VCC exceeds
VCCUV+, the IC enters Preheat mode and the gate driver outputs LO and HO
begin oscillating. LO and HO turn the external half-bridge MOSFETs on and off
causing the VS node to switch between the DC bus and COM. The charge pump
supply circuit connected to VS (CSNUB, DCP1, DCP2) then takes over as the
main supply circuit for the IC and VCC increases quickly from VCCUV+ up to the
internal zener clamp voltage (15.6V, typical). During the rising edges of VS from
COM to the DC bus each cycle, the charging current through the snubber
capacitor CSNUB also flows through the charge pump diode DCP1 to VCC.
During the falling edges of VS, the discharging current through CSNUB flows
from COM through the lower diode DCP2. In addition to reducing EMI due to the
dv/dt of the VS node, the value of CSNUB should also be large enough such that
enough current is supplied to VCC during preheat, ignition and running operating
conditions. CSNUB must not be too large otherwise VS will not commutate to the
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opposite rail within the fixed dead-time period (1.6usec, typical) and non-zerovoltage switching (non-ZVS) will occur. Additional filtering should also be added
to the charge pump circuit to protect VCC from high current spikes that can occur
in the charge pump due to hard-switching of VS or saturation of the lamp
resonant inductor. This additional filtering includes using an 18V zener diode for
DCP2, and, placing small current limiting resistors (R1 and R2) before each VCC
capacitor (CVCC2 and CVCC1).
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High-Side VBS Bootstrap Supply
The fourth function of supplying the high-side circuitry is performed by the
internal bootstrap MOSFET (BSFET) and external CBS capacitor. This internal
MOSFET is connected between VCC and VB and is only turned on during the LO
on-time each cycle. During the LO on-time, the lower half-bridge MOSFET is on
and VS is then connected to COM. Current flows from VCC, through the
bootstrap MOSFET, to VB, and the external capacitor CBS is charged up. During
the on-time of HO, VS is connected to the DC bus and the capacitor CBS
discharges slightly as it provides the high-side current for the turn-on of the
external high-side half-bridge MOSFET. The capacitor CBS is then replenished
again during each LO on-time. The value of CBS should be large enough such
that the voltage ripple does not decrease below the UVBS- threshold of the highside circuitry (9.0V, maximum). Typically 0.1uF is sufficient for most applications.
For higher frequency applications, the internal bootstrap MOSFET may not be
able to supply enough current to fully charge the high-side supply each cycle. In
this case, an external bootstrap diode is required to keep VBS high enough
above UVBS- (Figures 9a and 9b). Figure 9a shows LO and HO during operating
at about 168kHz and using the internal bootstrap MOSFET. The amplitude of HO
(which is equal to VBS) is below 10V and is very close to the nominal UVBSthreshold (8V, typical). Figure 9b shows the improved waveforms using an
external bootstrap diode. The amplitude of HO (and VBS) is now close to VCC
each cycle and well above the maximum UVBS-. For operating frequencies
above 100kHz, the VBS and HO amplitudes should be measured carefully to
make sure they are higher than about 10V.
Figure 9a, LO (yellow) and HO (red) using internal bootstrap MOSFET
(CBS=0.1uF, CHO=CLO=1nF).
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Figure 9b, LO (yellow) and HO (red) using an external bootstrap diode
(CBS=0.1uF, CHO=CLO=1nF).
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PCB Layout Guidelines
Figure 10 shows the IRS2168D ballast application circuit and Figure 11
shows an example of a good PCB layout. The layout is for a single layer board
and includes both SMT and through-hole components. The following critical
guidelines should be considered during the design of the layout:
1) Place all filter capacitors as close as possible to their respective pins. The
filter capacitors include CVCC2, CBS, CCS, CSD, COC, CCOMP, CVCO,
CPH and CVBUS. This will minimize the noise at each pin and prevent the
IC from malfunctioning.
2) The ground connection to the IC programming components and filter
capacitors should be connected directly to the COM pin of the IC. The
COM pin of the IC should then be connected to the circuit power ground at
a single point. Do not route the power ground through the COM
connection of the IC or the programming components.
3) The double filter at VCC (R1, CVCC1, R2, CVCC2) together with the
charge pump zener diode (DCP1) should be included in the circuit to filter
high current spikes from flowing to VCC. High current spikes can occur in
the charge pump during hard-switching or inductor saturation.
4) Keep the PFC MOSFET drain node (trace between DPFC, MPFC and
LPFC) as short as possible to reduce dv/dt noise.
5) Maintain proper creepage distance between high-voltage and low-voltage
traces to prevent arcing on the surface of the PCB.
6) Always use gate drive resistors (RLO, RHO, RPFC) between the gate
drive output pins (LO, HO, PFC) and the gates of the external power
MOSFETs. The gate drive resistors will prevent high currents from flowing
in and out of these pins which can occur due to the slewing of the Miller
capacitor between the drain and source of each external power MOSFET.
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LPFC:A
DPFC
Rectifier (+)
RVBUS1
RSUPPLY
LPFC:B
RVBUS2
CVBUS
RCPH
VBUS
CPH
16
CPH
VS
2
VCO
3
RFMIN
RPH
FMIN
4
CCOMP
COMP
5
RZX
ZX
6
7
RPFC
15
R4
To LRES
VB
14
R2
VCC
DCP1
R1
CSNUB
13
COM
12
LO
CVCC1 CVCC2
RLO
11
PFC
MLS
DCP2
R3
CS
7
MPFC
MHS
CBS
+
CVCO
IRS2168D
C BUS +
RHO
HO
1
RVBUS
10
OC
To Filament &
EOL Sensing
SD/EOL
8
9
RCS
ROC
COC
CSD
CCS
Return
DC Bus (-)
Figure 10, Ballast application circuit diagram.
RVBUS
Figure 11, Single-layer PCB layout example with SMT and through-hole
components.
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Conclusions
The additional design information presented here should help improve the
design of the ballast and help reduce potential problems. Ease of programming
the ballast frequency, correct design of the PFC inductor, resonant tank design
equations, design of the IC supply, and proper PCB layout guidelines, will all help
speed up design time, improve performance, and improve the manufacturability
and robustness of the final design.
A ballast design assistant (BDA) software is also available to help
calculate component values, graph operating points, simulate waveforms, and
generate complete schematics and bill of materials. The IRBDA software can be
downloaded directly from the International Rectifier website at: www.irf.com.
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