MICRO-LINEAR ML4832CS

July 2000
PRELIMINARY
ML4832*
Electronic Dimming Ballast Controller
GENERAL DESCRIPTION
FEATURES
The ML4832 is a complete solution for a dimmable/nondimmable, high power factor, high efficiency electronic
ballast. The BiCMOS ML4832 contains controllers for
“boost” type power factor correction as well as for a
dimming ballast.
■
Complete power factor correction and dimming
ballast control in one IC
■
Low distortion, high efficiency continuous boost,
average current sensing PFC section
■
Programmable start scenario for rapid or instant
start lamps
■
Lamp current feedback for dimming control
■
Variable frequency dimming and starting
■
Programmable restart for lamp out condition to
reduce ballast heating
■
Over-temperature shutdown replaces external
heat sensor for safety
■
PFC overvoltage comparator eliminates output
“runaway” due to load removal
■
Large oscillator amplitude and gain modulator
improves noise immunity
■
Low start-up current <0.5mA
The power factor circuit uses the average current sensing
method with a gain modulator and overvoltage protection.
This system produces a power factor of better than 0.99
with low input current THD at > 95% efficiency. Special
care has been taken in the design of the ML4832 to
increase system noise immunity by using a high amplitude
oscillator, and a current-fed multiplier. An overvoltage
protection comparator inhibits the PFC section in the
event of a lamp out or lamp failure condition.
The ballast section provides for programmable starting
scenarios with programmable preheat and lamp out-ofsocket interrupt times. The IC controls lamp output through
frequency modulation using lamp current feedback.
(* Indicates part is End Of Life as of July 1, 2000)
BLOCK DIAGRAM
INTERRUPT
7
8
RSET
RT/CT
LAMP FB
VARIABLE FREQUENCY
OSCILLATOR
LFB OUT
9
5
6
OUTPUT
DRIVERS
10
RX/CX
PRE-HEAT
AND INTERRUPT
TIMERS
OUT A
CONTROL
&
GATING LOGIC
OUT B
PFC OUT
2
4
3
1
18
IA OUT
14
13
15
IA+
ISINE
EA OUT
EA–/OVP
POWER
FACTOR
CONTROLLER
PGND
VCC
UNDER-VOLTAGE
AND THERMAL
SHUTDOWN
VREF
GND
12
16
17
11
1
ML4832
PIN CONFIGURATION
ML4832
18-Pin SOIC (S18)
ML4832
18-Pin DIP (P18)
EA OUT
IA OUT
ISINE
IA+
LAMP FB
LFB OUT
RSET
RT/CT
INTERRUPT
1
18
2
17
3
16
4
15
5
14
6
13
7
12
8
11
9
10
EA–/OVP
EA OUT
1
18
EA–/OVP
VREF
IA OUT
2
17
VREF
VCC
ISINE
3
16
VCC
IA+
4
15
PFC OUT
OUT A
LAMP FB
5
14
OUT A
OUT B
LFB OUT
6
13
OUT B
P GND
RSET
7
12
P GND
RT/CT
8
11
GND
INTERRUPT
9
10
RX/CX
PFC OUT
GND
RX/CX
TOP VIEW
TOP VIEW
PIN DESCRIPTION
PIN# NAME
FUNCTION
PIN#
NAME
FUNCTION
9
INTERRUPT
Input used for lamp-out detection
and restart. A voltage greater than
7.5 volts resets the chip and
causes a restart after a
programmable interval.
10
RX/CX
Sets the timing for the preheat,
dimming lockout, and interrupt
1
EA OUT
PFC error amplifier output and
compensation node
2
IA OUT
Output and compensation node of the
PFC average current transconductance
amplifier
3
ISINE
PFC gain modulator input
4
IA+
Non-inverting input of the PFC average
current transconductance amplifier
and peak current sense point of the
PFC cycle by cycle current limit
comparator
11
GND
Ground
12
P GND
Power ground for the IC
13
OUT B
Ballast MOSFET drive output
Inverting input of an error amplifier
used to sense (and regulate) lamp arc
current. Also the input node for
dimming control.
14
OUT A
Ballast MOSFET drive output
15
PFC OUT
Power Factor MOSFET drive
output
Output from the lamp current error
transconductance amplifier used for
lamp current loop compensation
16
VCC
Positive supply for the IC
17
VREF
Buffered output for the 7.5V
voltage reference
18
EA–/OVP
Inverting input to PFC error
amplifier and OVP comparator
input
5
6
7
8
2
LAMP FB
LFB OUT
RSET
External resistor which sets oscillator
FMAX, and RX/CX charging current
RT/CT
Oscillator timing components
ML4832
ABSOLUTE MAXIMUM RATINGS
Maximum Forced Voltage
(IA OUT) ................................................. –0.3V to 7.5V
Junction Temperature ............................................. 150°C
Storage Temperature Range...................... –65°C to 150°C
Lead Temperature (Soldering 10 sec.) ..................... 260°C
Thermal Resistance (qJA)
Plastic PDIP ..................................................... 70°C/W
Plastic SOIC ................................................... 100°C/W
Absolute maximum ratings are those values beyond which
the device could be permanently damaged. Absolute
maximum ratings are stress ratings only and functional
device operation is not implied.
Supply Current (ICC) ............................................... 60mA
Output Current, Source or Sink (OUT A, OUT B, PFC
OUT)
DC ................................................................... 250mA
Output Energy (capacitive load per cycle) ............... 1.5mJ
Gain Modulator ISINE Input ..................................... 10mA
Analog Inputs ....................................... –0.3V to VCC –2V
IA+ Input Voltage .............................................. –3V to 2V
Maximum Forced Voltage
(EA OUT, LFB OUT) ................................ –0.3V to 7.7V
Maximum Forced Current
(EA OUT, IA OUT, LFB OUT) ............................ ±20mA
OPERATING CONDITIONS
Temperature Range
ML4832C .................................................. 0°C to 85°C
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, RSET = 22.1kW, RT = 15.8kW, CT = 1.5nF, C(VCC) = 1µF, ISINE = 200µA, VCC = 12.5V,
TA = Operating Temperature Range (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
40
90
120
0.2
0.4
UNITS
PFC CURRENT SENSE AMPLIFIER
Output Low
ISINE = 0mA, VEA OUT = 0V,
VIA+ = –0.3V, RL = ¥
Output High
ISINE = 1.5mA,
VEA–/OVP = VIA+ = 0V, RL = ¥
Source Current
ISINE = 1.5mA,
VEA–/OVP = VIA+ = 0V,
VIA OUT = 6V, TJ = 25ºC
Sink Current
ISINE = 0mA, VIA OUT = 0.3V,
VIA+ = –0.6V
VEA OUT = 0V, VEA–/OVP = 5V,
TJ = 25ºC
µ
W
Small Signal Transconductance
V
6.3
6.8
V
–0.05
–0.15
–0.25
mA
0.03
0.07
0.16
mA
–0.3
–1.0
µA
55
90
PFC VOLTAGE FEEDBACK AMPLIFIER/LAMP CURRENT AMPLIFIER
Small Signal Transconductance
30
Input Voltage Range
–0.3
µ
W
Input Bias Current
5.0
V
0.2
0.4
V
7.1
7.5
7.8
V
Output Low
VLAMP FB = VEA–/OVP = 3V, RL = ¥
Output High
VLAMP FB = VEA–/OVP = 2V, RL = ¥
Source Current
VLAMP FB = VEA–/OVP = 0V,
VEA OUT = VLFB OUT = 7V,
TJ = 25ºC
–0.06
–0.15
–0.30
mA
Sink Current
VLAMP FB = VEA–/OVP = 5V,
VEA OUT = VLFB OUT = 0.3V,
TJ = 25ºC
0.06
0.12
0.28
mA
3
ML4832
ELECTRICAL CHARACTERISTICS
(Continued)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
GAIN MODULATOR
Output Voltage (VMUL)
ISINE = 100µA, VEA OUT = 3V
85
mV
ISINE = 300µA, VEA OUT = 3V
260
mV
ISINE =100µA, VEA OUT = 6V
200
mV
ISINE = 300µA, VEA OUT = 6V
600
mV
Output Voltage Limit
ISINE = 1.5mA, VEA–/OVP = 0V
Offset Voltage
ISINE Input Voltage
1.1
V
ISINE = 0µA, VEA–/OVP = 0V
15
mV
ISINE = 150µA, VEA–/OVP = 3V
15
mV
ISINE = 200µA
0.9
1
0.8
1.4
1.8
V
–0.85
–1.0
–1.15
V
PFC CURRENT — LIMIT COMPARATOR
Current-Limit Threshold
Propagation Delay
100mV step and 100mV overdrive
100
ns
OSCILLATOR
Initial Accuracy
TA = 25°C
Voltage Stability
VCCZ – 4.0V < VCC < VCCZ – 0.5V
72
Temperature Stability
Total Variation
Line, temperature
CT Discharge Current
80
kHz
1
%
2
%
69
Ramp Valley to Peak
CT Charging Current
76
83
2.5
kHz
V
VLAMP FB = 3V, VRT/CT = 2.5V,
VRX/CX = 0.9V (Preheat)
–90
–113
–130
µA
VLAMP FB = 3V, VRT/CT = 2.5V,
RX/CX = Open
–180
–230
–260
µA
4.0
5.5
7.0
mA
0.64
0.91
1.30
µs
7.4
7.5
7.6
V
VRT/CT = 2.5V
Output Drive Deadtime
REFERENCE SECTION
Output Voltage
TA = 25°C, IO = 1mA
Line regulation
VCCZ – 4.0V < VCC < VCCZ – 0.5V
8
25
mV
Load regulation
1mA < IO < 5mA
2
15
mV
Temperature stability
0.4
7.35
%
Total Variation
Line, load, temp
7.65
V
Output Noise Voltage
10Hz to 10kHz
50
µV
Long Term Stability
TJ = 125°C, 1000 hrs
5
mV
Initial Preheat Period
0.8
s
Subsequent Preheat Period
0.7
s
Start Period
1.2
s
Interrupt Period
5.7
s
PREHEAT AND INTERRUPT TIMER (RX = 680KW, CX = 4.7µF)
Pin 10 Charging Current
4
–24
–28
–33
µA
ML4832
ELECTRICAL CHARACTERISTICS (Continued)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
0.4
0.7
1.0
V
7.0
7.3
7.7
V
0.1
µA
PREHEAT AND INTERRUPT TIMER (RX = 680KW, CX = 4.7µF) CONTINUIED
Pin 10 Open Circuit Voltage
VCC < Start-up threshold
Pin 10 Maximum Voltage
Input Bias Current
VRX/CX = 1.2V
Preheat Lower Threshold
1.05
1.22
1.36
V
Preheat Upper Threshold
4.4
4.77
5.15
V
Interrupt Recovery Threshold
1.05
1.22
1.36
V
Start Period End Threshold
6.05
6.6
7.35
V
7.15
7.4
7.65
V
0.1
µA
INTERRUPT INPUT
Interrupt Threshold
Input Bias Current
RSET Voltage
2.4
2.5
2.6
V
OVP Threshold
2.65
2.75
2.85
V
Hysteresis
0.20
0.25
0.27
V
OVP COMPARATOR
Propagation Delay
1.4
µs
OUTPUTS
Output Voltage Low
Output Voltage High
IOUT = 20mA
0.1
0.2
V
IOUT = 200mA
1.0
2.0
V
IOUT = –20mA
VCC – 0.2
VCC – 0.1
V
IOUT = –200mA
VCC – 2.0
VCC – 1.0
V
Output Voltage Low in UVLO
IOUT = 10mA, VCC 8V
Output Rise/Fall Time
CL = 1000pF
0.2
20
V
ns
UNDER-VOLTAGE LOCKOUT AND BIAS CIRCUITS
IC Shunt Voltage (VCCZ)
ICC = 15mA
Start-up Current
Operating Current
14.2
15.0
15.8
V
VCC = Start-up threshold –0.2V
0.34
0.48
mA
VCC = 12.5V, VIA+ = 0V,
VEA–/OVP = VLAMP FB = 2.3V,
IA OUT = open
RT = 16.2kW, RSET = 22.1kW
VCC = 12.5V, CL = 0
5.5
8.0
mA
Start-up Threshold
VCC – 1.2 VCCZ – 1.0 VCC – 0.8
V
Shutdown Threshold
VCC – 5.5 VCCZ – 5.0 VCC – 4.5
V
Shutdown Temperature (TJ)
120
°C
Hysteresis (TJ)
30
°C
Note 1:
Limits are guaranteed by 100% testing, sampling or correlation with worst case test conditions.
5
ML4832
FUNCTIONAL DESCRIPTION
OVERVIEW
GAIN MODULATOR
The ML4832 consists of an average current controlled
continuous boost power factor front end section with a
flexible ballast control section. Start-up and lamp-out retry
timing are controlled by the selection of external timing
components, allowing for control of a wide variety of
different lamp types. The ballast section controls the lamp
power using frequency modulation (FM) with additional
programmability provided to adjust the VCO frequency
range. This allows for the IC to be used with a variety of
different output networks.
The ML4832 gain modulator provides high immunity to
the disturbances caused by high power switching. The
rectified line input sine wave is converted to a current via
a series resistor. In this way, small amounts of ground noise
produce an insignificant effect on the reference to the
PWM comparator.
The output of the gain modulator appears on the positive
terminal of the IA amplifier to form the reference for the
current error amplifier. Please refer to Figure 1.
POWER FACTOR SECTION
The ML4832 power factor section is an average current
sensing boost mode PFC control circuit which is
architecturally similar to that found in the ML4821. For
detailed information on this control architecture, please
refer to Application Note 16 and the ML4821 data sheet.
VMUL =
ISINE × 1VEA−0.7V6
34
. mA
(1)
where: ISINE is the current in the dropping resistor,
VEA is the output of the error amplifier (Pin 1).
The output of the gain modulator is limited to 1.0V.
7
10
16
17
11
2
LFB OUT
RSET
RX/CX
VARIABLE
FREQUENCY
OSC
PREHEAT
TIMER
UNDER-VOLTAGE
AND THERMAL
SHUTDOWN
VREF
–
+
–VMUL+
IA +
8
R
S
–
PFC OUT
Q
15
+
–1V
PWM (PFC)
OUT A
Q
14
+
T
GAIN
MODULATORS
ISINE
OUT B
Q
13
EA OUT
–
EA –/OVP
2.5V
–
+
2.75V
+
OVP
Figure 1. ML4832 Block Diagram
6
9
VREF
RT/CT
IA OUT
–
18
INTERRUPT
5
GND
7k
1
LAMP FB
–
–
3
2.5V
+
VCC
7k
4
+
6
P GND
12
ML4832
FUNCTIONAL DESCRIPTION (Continued)
TRANSCONDUCTANCE AMPLIFIERS
AVERAGE CURRENT AND OUTPUT VOLTAGE
REGULATION
The PWM regulator in the PFC control section will act to
offset the positive voltage caused by the multiplier output
by producing an offsetting negative voltage on the current
sense resistor at IA+. A cycle-by-cycle current limit is
included to protect the MOSFET from high speed current
transients. When the voltage at IA+ goes negative by more
than 1V, the PWM cycle is terminated.
The PFC voltage feedback, PFC current sense, and the
loop current amplifiers are all implemented as operational
transconductance amplifiers. They are designed to have
low small signal forward transconductance such that a
large value of load resistor (R1) and a low value ceramic
capacitor (<1µF) can be used for AC coupling (C1) in the
frequency compensation network. The compensation
network shown in Figure 2 will introduce a zero and a
pole at:
For more information on compensating the average
current and boost voltage error amplifier loops, see
ML4821 data sheet.
fZ =
OVERVOLTAGE PROTECTION AND INHIBIT
The OVP pin serves to protect the power circuit from
being subjected to excessive voltages if the load should
change suddenly (lamp removal). A divider from the high
voltage DC bus sets the OVP trip level. When the voltage
on EA–/OVP exceeds 2.75V, the PFC transistors are
inhibited. The ballast section will continue to operate.
18
–
2.5V
+
1
2π R1C1
fP =
1
2π R1C 2
(2)
Figure 3 shows the output configuration for the operational
transconductance amplifiers.
A DC path to ground or VCC at the output of the
transconductance amplifiers will introduce an offset error.
R1
C2
C1
Figure 2. Compensation Network
CURRENT
MIRROR
IN
OUT
IQ +
IQ –
iO
gmVIN
2
io = gmVIN
gmVIN
2
VIN Differential
0
Linear Slope Region
IN
OUT
CURRENT
MIRROR
Figure 3. Output Configuration
Figure 4. Transconductance Amplifier Characteristics
7
ML4832
FUNCTIONAL DESCRIPTION (Continued)
The magnitude of the offset voltage that will appear at
the input is given by VOS = io/gm. For an io of 1mA and a
gm of 0.05 µmhos the input referred offset will be 20mV.
Capacitor C1 as shown in Figure 2 is used to block the
DC current to minimize the adverse effect of offsets.
Slew rate enhancement is incorporated into all of the
operational transconductance amplifiers in the ML4832.
This improves the recovery of the circuit in response to
power up and transient conditions. The response to large
signals will be somewhat non-linear as the
transconductance amplifiers change from their low to
high transconductance mode. This is illustrated in
Figure 4.
FOSC =
t CHG = RT C T In
The VCO frequency ranges are controlled by the output
of the LFB amplifier. As lamp current decreases, LFB
OUT rises in voltage, causing the CT charging current to
decrease, thereby causing the oscillator frequency to
decrease. Since the ballast output network attenuates
high frequencies, the power to the lamp will be
increased.
VREF
+ ICH R T − VTL
+ ICH RT − VTH
1
0.51× RT C T
1.25/3.75
1. The output of the preheat timer
2. The voltage at LFB OUT
In preheat condition, charging current is fixed at
ICHG (PREHEAT) =
25
.
RSET
CONTROL
tDIS
–
CT
5.5mA
VTH = 3.75V
CT
VTL = 1.25V
Figure 5. Oscillator Block Diagram and Timing
8
(5)
When LFB OUT is high, ICH = 0 and the minimum
frequency occurs. The charging current varies according to
two control inputs to the oscillator:
+
8
(4)
This assumes that tCHG >> tDIS.
CLOCK
RT/CT
The oscillator’s minimum frequency is set when ICH = 0
where:
VREF
ICHG
RT
REF
REF
The oscillator frequency is determined by the following
equations:
17
V
V
FOSC ≅
OSCILLATOR
(3)
and
BALLAST OUTPUT SECTION
The IC controls output power to the lamps via frequency
modulation with non-overlapping conduction. This
means that both ballast output drivers will be low during
the discharging time tDIS of the oscillator capacitor CT.
1
t CHG + tDIS
tCHG
(6)
ML4832
FUNCTIONAL DESCRIPTION (Continued)
In running mode, charging current decreases as the VPIN6
rises from 0V to VOH of the LAMP FB amplifier. The
highest frequency will be attained when ICHG is highest,
which is attained when LFB OUT is at 0V:
ICHG(0) =
5
(7)
R SET
Highest lamp power, and lowest output frequency are
attained when LFB OUT is at its maximum output voltage
(VOH).
In this condition, the minimum operating frequency of the
ballast is set per (5) above.
For the IC to be used effectively in dimming ballasts with
higher Q output networks a larger CT value and lower RT
value can be used, to yield a smaller frequency excursion
over the control range (VLFB OUT). The discharge current is
set to 5.5mA. Assuming that IDIS >> IRT:
t DIS(VCO) ≅ 600 × CT
(8)
IC BIAS, UNDER-VOLTAGE LOCKOUT AND THERMAL
SHUTDOWN
The IC includes a shunt regulator which will limit the
voltage at VCC to 15V (VCCZ). The IC should be fed with
a current limited source, typically derived from the ballast
transformer auxiliary winding. When VCC is below
VCCZ – 1.1V, the IC draws less than 0.48mA of quiescent
current and the outputs are off. This allows the IC to start
using a “bleed resistor” from the rectified AC line.
To help reduce ballast cost, the ML4832 includes a
temperature sensor which will inhibit ballast operation if
the IC’s junction temperature exceeds 120°C. In order to
use this sensor in lieu of an external sensor, care should be
taken when placing the IC to ensure that it is sensing
temperature at the physically appropriate point in the
ballast. The ML4832’s die temperature can be estimated
with the following equation:
T J ≅ TA × PD × 65° C / W
(9)
STARTING, RE-START, PREHEAT AND INTERRUPT
The lamp starting scenario implemented in the ML4832
is designed to maximize lamp life and minimize ballast
heating during lamp out conditions.
The circuit in Figure 7 controls the lamp starting scenarios:
Filament preheat and lamp out interrupt. CX is charged
with a current of IRSET/4 and discharged through RX. The
voltage at CX is initialized to 0.7V (VBE) at power up. The
time for CX to rise to 4.8V is the filament preheat time.
During that time, the oscillator charging current (ICHG) is
2.5/RSET. This will produce a high frequency for filament
preheat, but will not produce sufficient voltage to ignite
the lamp.
After cathode heating, the inverter frequency drops to
FMIN causing a high voltage to appear to ignite the lamp.
If the voltage does not drop when the lamp is supposed to
have ignited, the lamp voltage feedback coming into pin 9
rises to above VREF, the CX charging current is shut off and
the inverter is inhibited until CX is discharged by RX to the
1.2V threshold. Shutting off the inverter in this manner
prevents the inverter from generating excessive heat when
VCC VCCZ
VON
0.625
RSET
VOFF
RX/CX
+
10
HEAT
CX
t
ICC
1.2/4.8
–
RX
6.8
5.5mA
+
1.2/6.8
DIMMING
LOCKOUT
–
INHIBIT
R
0.34mA
t
9
INT
VREF
Figure 6. Typical VCC and ICC Waveforms when
the ML4832 is Started with a Bleed Resistor from
the Rectified AC Line and Bootstrapped from an
Auxiliary Winding.
–
Q
S
+
Figure 7. Lamp Preheat and Interrupt Timers
9
ML4832
FUNCTIONAL DESCRIPTION (Continued)
the lamp fails to strike or is out of socket. Typically this
time is set to be fairly long by choosing a large value
of RX.
LFB OUT is ignored by the oscillator until CX reaches 6.8V
threshold. The lamps are therefore driven to full power and
then dimmed. The CX pin is clamped to about 7.5V.
A summary of the operating frequencies in the various
operating modes is shown below.
OPERATING MODE
OPERATING FREQUENCY
Preheat
[F(MAX) to F(MIN)]
2
Dimming
Lock-out
F(MIN)
DIMMING
CONTROL
F(MIN) TO F(MAX)
6.8
4.8
RX/CX
1.2
.65
0
HEAT
DIMMING
LOCKOUT
7.5
INT
INHIBIT
Figure 8. Lamp Starting and Restart Timing
10
ML4832
TYPICAL APPLICATIONS
Figures 9 and 10 show ballast schematics, both nondimming and dimming. These are power-factor corrected
60W ballasts designed to operate two series connected
F32T8 fluorescent lamps. Both Schematics, Figures 9 and
10, are of previously published ML4831 circuits that have
been modified for ML4832 compatibility. The value
changes and component additions made for ML4832
compatibility were for different amplifier compensation,
bootstrap/bias and protection and do not effect the validity
of the circuit description, operational information or
equations.
TO CONVERT FROM AN EXISTING NON-DIMMING
ML4831 TO THE ML4832:
TO CONVERT FROM AN EXISTING DIMMING ML4831
TO THE ML4832:
Resistors
Resistors
Change:
Add:
Delete:
to
51kW, 1/4 W, 5% carbon film
to
51kW, 1/4 W, 5% carbon film
R6, R7 to
866kW, 1/4 W, 1%, metal film
R6, R11 to
866kW, 1/4 W, 1%, metal film
R7
to
75kW, 1/4 W, 5%, carbon film
R7
to
75kW, 1/4 W, 5%, carbon film
R18
to
470W, 1/4 W, 5%, carbon film
R18
to
470W, 1/4 W, 5%, carbon film
R13
to
5.76kW, 1/4 W, 1%, metal film
R13
to
5.76kW, 1/4 W, 1%, metal film
R14
to
499kW, 1/4 W, 5%, carbon film
R14
to
499kW, 1/4 W, 5%, carbon film
R24
75kW, 1/4 W, 5%, carbon film
R26
to
200kW, 1/4 W, 5%, carbon film
R22
51W, 1/4 W, 5%, carbon film
R23
100W, 1/4 W, 5%, carbon film
R4
Add:
Delete:
C5
to
10nF, 63V, 10% ceramic
Capacitors
C7
to
180pF, 100V, 5% ceramic
Change:
C11
to
C12
R4
R32
75kW, 1/4 W, 5%, carbon film
R30
51W, 1/4 W, 5%, carbon film
R31
100W, 1/4 W, 5%, carbon film
R9
C5
to
10nF, 63V, 10% ceramic
1nF, 100V, 10% ceramic
C7
to
180pF, 100V, 5% ceramic
to
100nF, 100V, 10% ceramic
C25
to
1nF, 100V, 10% ceramic
C18
to
100µF, 16V, 20% electrolytic
C12
to
100nF, 100V, 10% ceramic
C20
to
100µF, 25V, 20% electrolytic
C24
to
100µF, 16V, 20% electrolytic
33nF, 50V, 20% ceramic
C20
to
100µF, 25V, 20% electrolytic
C23
Magnetics
Change:
Add:
R9
Capacitors
Change:
Change:
Add:
T1
to
TSD-882
C27
33nF, 50V, 20% ceramic
C26
100nF, 100V, 10% ceramic
Diodes
Delete:
D10, D13
Magnetics
Change:
T1
to
TSD-882
11
12
L1
Figure 9. 220V Non-Dimming Ballast
R23
100Ω
R1
1.0Ω
D4
1A
R4
51kΩ
C7
C5 C12 C11
10nF 100nF 1nF 180pF
R14
499kΩ
D6
1A
D5
1A
C2
2.2nF
D3
C1* C3 1A
2.2nF 0.15µF
*Note: Only One Chassis Ground
NEUTRAL
220 VAC
F1
8
7
D9
1A
9
10
R5
15.4kΩ
C6
2.2nF
R6
866kΩ
R8
22Ω
11
10
9
C4
R15
0.1µF 324k
12
8
13
14
15
16
7
6
5
4
3
17
18
1
2
R21
5kΩ
C13
10µF
C10
47µF
D7
1A
Q1
2.5A
R18 470Ω
T1
D12
1A
R10
11.5kΩ
D13
0.1A
C20
R11 100µF
866kΩ
C23
33nF
D2
1A
D1
1A
ML4832
HOT
TP3
C18
100µF
R24
75kΩ
R7
75kΩ
7
6
C14
C15
C16
0.22µF 0.22µF 100pF
TP2
R13
5.76kΩ
R12
442kΩ
R20
442kΩ
8
1
2
3
R22
51Ω
C17
1µF
T2
TP1
R19
51Ω
R3
9.1kΩ
R2
1kΩ
Q3
IRF820
R17
51Ω
Q2
IRF820
C19
D11
IN4148
C22
33nF
7
6
8
1
9
2
3
4
C21
0.001µF
C8
4700pF
C9
33nF
T3
R16
1kΩ
D8
IN4148
TP4
TP5
B
B
Y
Y
R
R
ML4832
HOT
L2
C27
33nF
R31
100Ω
R1
1.0Ω
D2
1A
R6
866kΩ
R11
866kΩ
R5
15.4kΩ
R3
220kΩ
D1
1A
C4
C12 C25 C7
C5
10nF 100nF 1nF 180pF 3.3µF
R2
4.3kΩ
D4
1A
D3
1A
R4
R14
499kΩ 51kΩ
D6
1A
D5
1A
C3
0.15nF
C2
2.2nF
C1*
2.2nF
*Note: Only One Chassis Ground
NEUTRAL
220 VAC
F1
D9
1A
9
10
C6
2.2nF
10
TP3
R15
324kΩ
11
9
12
13
14
15
16
8
7
6
5
4
3
17
18
2
1
R18
470Ω
R8
22Ω
C13
10µF
C10
47µF
Q1
2.5A
D7
1A
R25
5kΩ
T1
R10
11.5kΩ
C20
100µF
8
7
D15
1A
ML4832
L1
R16
10kΩ
C15
0.22µF
C24
100µF
R32
75kΩ
R7
75kΩ
C14
0.22µF
D16
5.1V
R29
1.3kΩ
R13
5.76kΩ
R12
442kΩ
R23
442kΩ
8
1
2
3
R30
51
C17
1µF
T2
C16
100pF
7
6
Q2
2.5A
Q3
2.5A
C21
1µF
R20
10kΩ
D11
0.1A
TP2
TP1
R19
51Ω
R17
51Ω
R22
11kΩ
R26
200kΩ
R24
64.9kΩ
6
5
2
3
8
3
9
4
1
2
C9
15nF
T4
–
+
4
IC1
–
+
8
R27
200kΩ
C8
4700pF
7
6
C26
100nF
C22
0.33µF
TP4
7
1
TP5
10
1
D8
0.1A
R28
20kΩ
6
T5
5
B
B
Y
Y
R
R
ML4832
Figure 10. 220V Dimming Ballast
13
ML4832
PHYSICAL DIMENSIONS inches (millimeters)
Package: P18
18-Pin PDIP
0.890 - 0.910
(22.60 - 23.12)
18
0.240 - 0.260 0.295 - 0.325
(6.09 - 6.61) (7.49 - 8.26)
PIN 1 ID
1
0.045 MIN
(1.14 MIN)
(4 PLACES)
0.050 - 0.065
(1.27 - 1.65)
0.100 BSC
(2.54 BSC)
0.015 MIN
(0.38 MIN)
0.170 MAX
(4.32 MAX)
SEATING PLANE
0.016 - 0.022
(0.40 - 0.56)
0.125 MIN
(3.18 MIN)
0º - 15º
0.008 - 0.012
(0.20 - 0.31)
Package: S18
18-Pin SOIC
0.449 - 0.463
(11.40 - 11.76)
18
0.291 - 0.301 0.398 - 0.412
(7.39 - 7.65) (10.11 - 10.47)
PIN 1 ID
1
0.024 - 0.034
(0.61 - 0.86)
(4 PLACES)
0.050 BSC
(1.27 BSC)
0.095 - 0.107
(2.41 - 2.72)
0º - 8º
0.090 - 0.094
(2.28 - 2.39)
14
0.012 - 0.020
(0.30 - 0.51)
SEATING PLANE
0.005 - 0.013
(0.13 - 0.33)
0.022 - 0.042
(0.56 - 1.07)
0.009 - 0.013
(0.22 - 0.33)
ML4832
ORDERING INFORMATION
© Micro Linear 1999.
PART NUMBER
TEMPERATURE RANGE
PACKAGE
ML4832CP (End of Life)
ML4832CS (Obsolete)
0°C to 85°C
0°C to 85°C
Molded PDIP (P18)
SOIC (S18)
is a registered trademark of Micro Linear Corporation. All other trademarks are the property of their respective owners.
Products described herein may be covered by one or more of the following U.S. patents: 4,897,611; 4,964,026; 5,027,116; 5,281,862; 5,283,483;
5,418,502; 5,508,570; 5,510,727; 5,523,940; 5,546,017; 5,559,470; 5,565,761; 5,592,128; 5,594,376; 5,652,479; 5,661,427; 5,663,874; 5,672,959;
5,689,167; 5,714,897; 5,717,798; 5,742,151; 5,747,977; 5,754,012; 5,757,174; 5,767,653; 5,777,514; 5,793,168; 5,798,635; 5,804,950; 5,808,455;
5,811,999; 5,818,207; 5,818,669; 5,825,165; 5,825,223; 5,838,723; 5.844,378; 5,844,941. Japan: 2,598,946; 2,619,299; 2,704,176; 2,821,714.
Other patents are pending.
Micro Linear reserves the right to make changes to any product herein to improve reliability, function or design. Micro Linear does not assume any
liability arising out of the application or use of any product described herein, neither does it convey any license under its patent right nor the rights of
others. The circuits contained in this data sheet are offered as possible applications only. Micro Linear makes no warranties or representations as to
whether the illustrated circuits infringe any intellectual property rights of others, and will accept no responsibility or liability for use of any application
herein. The customer is urged to consult with appropriate legal counsel before deciding on a particular application.
02/19/99 Printed in U.S.A.
DS4832-01
2092 Concourse Drive
San Jose, CA 95131
Tel: 408/433-5200
Fax: 408/432-0295
15