MARKTECH MAX8759ETI

19-3874; Rev 1; 2/06
Low-Cost, SMBus, CCFL Backlight Controller
The MAX8759 integrated cold-cathode fluorescent lamp
(CCFL) inverter controller is designed to drive CCFLs
using a full-bridge resonant inverter. The resonant operation ensures reliable striking and provides near-sinusoidal
waveforms over the entire input range. The controller
operates over a wide input-voltage range of 4.5V to 28V
with high power to light efficiency. The device also
includes safety features that effectively protect against
single-point fault conditions such as lamp-out, secondary
overvoltage, and secondary short-circuit faults.
The MAX8759 provides accurate lamp-current regulation (±2.5%) for superior CCFL inverter performance.
The lamp current is adjustable with an external resistor;
10:1 dimming range can be achieved by turning the
CCFL on and off using a digital pulse-width modulation
(DPWM) method, while maintaining the lamp-current
constant. The MAX8759 provides three mechanisms for
controlling brightness: 2-wire SMBus™-compatible
interface, external ambient-light sensor (ALS), or system PWM control. The MAX8759 supports Intel display
power-saving technology (DPST) to maximize battery
life. The device includes two lamp-current feedback
input pins that support dual-lamp applications with a
minimum number of external components.
The MAX8759 controls a full-bridge inverter for maximum efficiency and directly drives four external n-channel power MOSFETs. An internal 5.35V linear regulator
powers the MOSFET drivers and most of the internal
circuitry. The MAX8759 is available in a space-saving,
28-pin, thin QFN package and operates over a -40°C to
+85°C temperature range.
Features
♦ Accurate Dimming Control Using SMBus, PWM
Interface, or Ambient Light Sensor
♦ 10:1 Dimming Range with 256-Step Resolution
♦ Resonant-Mode Operation
Longer Lamp Life with Near Sinusoidal LampCurrent Waveform
Guaranteed Striking Capability
High-Power-to-Light Efficiency
♦ Wide Input-Voltage Range (4.5V to 28V)
♦ Input Feed-Forward for Excellent Line Rejection
♦ ±2.5% Lamp-Current Regulation
♦ Adjustable 1.5% Accurate DPWM Frequency
♦ Dual Lamp-Current Feedback Inputs
♦ Comprehensive Fault Protection
Secondary Voltage Limiting
Primary Current Limit with Lossless Sensing
Lamp-Out Protection with Adjustable Timeout
Secondary Short-Circuit Protection
♦ Small 28-Pin, 5mm x 5mm, Thin QFN Package
Minimal Operating Circuit
Applications
Notebooks
LCD Monitors
Automotive Infotainment
MAX8759
Ordering Information
PART
TEMP RANGE
PINPACKAGE
MAX8759ETI+
-40°C to +85°C
28 Thin QFN-EP*
5mm × 5mm
PKG
CODE
T2855-6
+ Denotes lead-free package.
*EP = Exposed pad.
Pin Configuration appears at end of data sheet.
SMBus is a trademark of Intel Corp.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX8759
General Description
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
ABSOLUTE MAXIMUM RATINGS
BATT to GND..........................................................-0.3V to +30V
BST1, BST2 to GND ...............................................-0.3V to +36V
BST1 to LX1, BST2 to LX2 ........................................-0.3V to +6V
FREQ, VCC, VDD to GND .........................................-0.3V to +6V
SDA, SCL to GND.....................................................-0.3V to +6V
ALS, COMP, PWMI, PWMO,
TFLT, DEL, VALS to GND .......................-0.3V to (VCC + 0.3V)
GH1 to LX1 ..............................................-0.3V to (VBST1 + 0.3V)
GH2 to LX2 ..............................................-0.3V to (VBST2 + 0.3V)
GL1, GL2 to GND .......................................-0.3V to (VDD + 0.3V)
IFB1, IFB2, ISEC, VFB to GND ....................................-3V to +6V
PGND1, PGND2 to GND .......................................-0.3V to +0.3V
Continuous Power Dissipation (TA = +70°C)
28-Pin Thin QFN 5mm x 5mm
(derate 21.3mW/°C above +70°C) .............................1702mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, VBATT = 12V, VCC = VDD, TA = 0°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.)
PARAMETER
BATT Input Voltage Range
CONDITIONS
MAX
4.5
5.5
VCC = VDD = open
5.5
28.0
VBATT = 28V
MAX8759 is enabled
BATT Quiescent Current, Shutdown
MAX8759 is disabled
VCC Output Voltage, Normal Operation
MAX8759 is enabled, 6V < VBATT < 28V,
0 < ILOAD < 10mA
VCC Output Voltage, Shutdown
MAX8759 is disabled, no load
2.5
VBATT = VCC = 5V
UNITS
V
mA
0.1
2
µA
5.2
5.35
5.5
V
3.5
4.3
5.5
V
VCC rising (leaving lockout)
VCC falling (entering lockout)
5
5
4.3
3.7
VCC Undervoltage Lockout Hysteresis
VCC POR Threshold
TYP
VCC = VDD = VBATT
BATT Quiescent Current
VCC Undervoltage Lockout Threshold
MIN
230
Rising edge
VCC POR Hysteresis
V
mV
1.75
V
50
mV
GH1, GH2, GL1, GL2 On-Resistance,
Low State
ITEST = 100mA, VCC = VDD = 5V
3
6
Ω
GH1, GH2, GL1, GL2 On-Resistance,
High State
ITEST = 100mA, VCC = VDD = 5V
10
18
Ω
BST1, BST2 Leakage Current
VBST_ = 12V, VLX_ = 7V
4
10
µA
Resonant Frequency Range
Guaranteed by design
80
kHz
700
ns
Minimum On-Time
30
350
Maximum Off-Time
500
40
60
80
µs
Current-Limit Threshold
LX1 - PGND1, LX2 - PGND2
415
430
445
mV
Zero-Current-Crossing Threshold
LX1 - PGND1, LX2 - PGND2
3
8
13
mV
Current-Limit Leading-Edge Blanking
IFB1, IFB2 Input-Voltage Range
350
-3
ns
+3
V
IFB1 Regulation Point
765
785
805
mV
IFB2 Regulation Point
780
800
820
mV
2
_______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
(Circuit of Figure 1, VBATT = 12V, VCC = VDD, TA = 0°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.)
PARAMETER
IFB1, IFB2 Input Bias Current
CONDITIONS
0 < VIFB1,2 < 3V
-3
-3V < VIFB1,2 < 0
-230
IFB1, IFB2 Lamp-Out Threshold
IFB1, IFB2 to COMP Transconductance
MIN
0.5V < VCOMP < 4V
COMP Output Impedance
TYP
MAX
+3
UNITS
µA
575
600
625
mV
60
100
160
µS
6
12
24
MΩ
COMP Discharge Current During Overvoltage
or Overcurrent Fault
VVFB = 2.6V or VISEC = 1.5V
500
1000
2000
µA
COMP Discharge Current During DPWM
Off-Time
VCOMP = 1.5V
90
110
130
µA
DPWM Rising-to-Falling Ratio
VIFB1,2 = 0
ISEC Input Voltage Range
ISEC Overcurrent Threshold
ISEC Input Bias Current
2.5
-3
+3
V
1.26
V
-0.3
+0.3
µA
-4
+4
V
450
MΩ
1.18
VISEC = 1.25V
VFB Input Voltage Range
VFB Input Impedance
150
1.21
300
VFB Overvoltage Threshold
2.2
2.3
2.4
V
VFB Undervoltage Threshold
210
240
280
mV
VFB Undervoltage Delay
DPWM Oscillator Frequency
RFREQ = 169kΩ
250
RFREQ = 169kΩ, TA = +25°C to +85°C
207
210
213
RFREQ = 169kΩ
205
210
215
RFREQ = 340kΩ
106
RFREQ = 100kΩ
PWMO Output Impedance
PWMI Input High Voltage
40
60
kΩ
0.7
V
2.1
PWMI Input Hysteresis
V
300
PWMI Input Bias Current
PWMI Input Frequency Range
mV
-0.3
+0.3
µA
5
50
kHz
5
LSB
%
PWMI Full-Range Accuracy
PWMI duty cycle = 100%
98
PWMI duty cycle = 50%
48
50
52
PWMI duty cycle = 0%
9.7
10.0
10.3
ALS Full-Adjustment Range
100
0
ALS Full-Range Accuracy
ALS Input Bias Current
-0.1
VALS Output Voltage
MAX8759 is enabled, 6V < VBATT < 28V,
ILOAD = 1mA
VALS Leakage Current
MAX8759 is disabled, VALS = GND
VALS On-Resistance
MAX8759 is enabled
Hz
343
20
PWMI Input Low Voltage
PWMI Brightness Setting
µs
5.10
5.30
-3
30
1.8
V
5
LSB
+0.1
µA
5.50
V
+3
µA
60
Ω
_______________________________________________________________________________________
3
MAX8759
ELECTRICAL CHARACTERISTICS (continued)
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VBATT = 12V, VCC = VDD, TA = 0°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.)
PARAMETER
Zero-Crossing Delay
Maximum Zero-Crossing Delay
DEL Disable Threshold
TFLT Charge Current
TFLT Trip Threshold
MIN
TYP
MAX
VBATT = 9V, RTHR = 120kΩ
CONDITIONS
0
0.15
0.30
VBATT = 12V, RTHR = 120kΩ
1.50
1.80
2.10
VBATT = 18V, RTHR = 120kΩ
3.2
3.8
4.4
DEL rising
DEL falling
4.5
3.8
VISEC < 1.25V and VIFB < 540mV; VFLT = 2V
0.9
1.0
1.1
VISEC < 1.25V and VIFB > 660mV; VFLT = 2V
-1.5
-1.2
-0.8
VISEC > 1.25V and VIFB > 660mV; VFLT = 2V
115
135
155
Rising edge
3.7
4
SDA, SCL, Input Low Voltage
SDA, SCL, Input High Voltage
SDA Output Low Sink Current
VSDA = 0.4V
SMBus Free Time
4.7
µA
V
V
mV
+1
µA
100
kHz
4
mA
10
tBUF
V
V
-1
SMBus Frequency
µs
4.3
100
SDA, SCL, Input Bias Current
µs
0.7
2.1
SDA, SCL, Input Hysteresis
UNITS
1
µs
SCL Serial Clock High Period
tHIGH
4
µs
SCL Serial Clock Low Period
tLOW
4.7
µs
START Condition Setup Time
tSU:STA
4.7
µs
START Condition Hold Time
tHD:STA
4
µs
STOP Condition Setup Time from SCL
tSU:STO
4
µs
SDA Valid to SCL Rising-Edge Setup Time,
Slave Clocking in Data
tSU:DAT
250
ns
SCL Falling Edge to SDA Transition
tHD:DAT
0
ns
SCL Falling Edge to SDA Valid, Reading Out
Data
tDV
200
ns
4
_______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
MAX8759
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, VBATT = 12V, VCC = VDD, TA = -40°C to +85°C.) (Note 1)
PARAMETER
BATT Input Voltage Range
CONDITIONS
MIN
5.5
VCC = VDD = open
5.5
28.0
VBATT = 28V
5
VBATT = VCC = 5V
5
MAX8759 is enabled
VCC Output Voltage, Normal Operation
MAX8759 is enabled, 6V < VBATT < 28V,
0 < ILOAD < 10mA
5.2
MAX8759 is disabled, no load
3.5
VCC Undervoltage Lockout Threshold
MAX
4.5
BATT Quiescent Current
VCC Output Voltage, Shutdown
TYP
VCC = VDD = VBATT
VCC rising (leaving lockout)
VCC falling (entering lockout)
UNITS
V
mA
5.5
V
5.5
V
4.3
3.7
V
GH1, GH2, GL1, GL2 On-Resistance,
Low State
ITEST = 100mA, VCC = VDD = 5V
6
Ω
GH1, GH2, GL1, GL2 On-Resistance,
High State
ITEST = 100mA, VCC = VDD = 5V
18
Ω
Resonant Frequency Range
Guaranteed by design
30
80
kHz
Minimum On-Time
350
700
ns
Maximum Off-Time
40
80
µs
410
450
mV
mV
Current-Limit Threshold
LX1 - PGND1, LX2 - PGND2
Zero-Current Crossing Threshold
LX1 - PGND1, LX2 - PGND2
IFB1, IFB2 Input Voltage Range
IFB1 Regulation Point
IFB2 Regulation Point
IFB1, IFB2 Input Bias Current
-3V < VIFB1,2 < 0
IFB1, IFB2 Lamp-Out Threshold
IFB1, IFB2 to COMP Transconductance
0.5V < VCOMP < 4V
COMP Output Impedance
3
13
-3
+3
V
760
810
mV
775
825
mV
565
635
mV
60
160
µS
6
25
MΩ
-230
µA
COMP Discharge Current During Overvoltage
or Overcurrent Fault
VVFB = 2.6V or VISEC = 1.5V
500
2000
µA
COMP Discharge Current During DPWM
Off-Time
VCOMP = 1.5V
90
130
µA
-3
+3
V
1.18
1.26
V
ISEC Input Voltage Range
ISEC Overcurrent Threshold
VFB Input Voltage Range
-4
+4
V
VFB Input Impedance
150
450
MΩ
VFB Overvoltage Threshold
2.2
2.4
V
210
280
mV
203
217
Hz
20
60
kΩ
VFB Undervoltage Threshold
DPWM Oscillator Frequency
PWMO Output Impedance
RFREQ = 169kΩ
_______________________________________________________________________________________
5
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VBATT = 12V, VCC = VDD, TA = -40°C to +85°C.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
PWMI Input Low Voltage
PWMI Input High Voltage
5
PWMI duty cycle = 100%
98
52
10.3
0
1.8
V
5.10
5.50
V
60
Ω
MAX8759 is enabled
TFLT Trip Threshold
VBATT = 9V, RTHR = 100kΩ
0
0.3
VBATT = 12V, RTHR = 100kΩ
1.50
2.10
VBATT = 16V, RTHR = 100kΩ
3.2
4.4
DEL rising
DEL falling
4.5
3.9
VISEC < 1.25V and VIFB < 540mV; VFLT = 2V
0.8
1.2
VISEC < 1.25V and VIFB > 660mV; VFLT = 2V
-1.5
-0.8
VISEC > 1.25V and VIFB > 660mV; VFLT = 2V
115
155
Rising edge
3.7
SDA, SCL, Input Low Voltage
SDA, SCL, Input High Voltage
SDA Output Low-Sink Current
VSDA = 0.4V
tBUF
µs
V
µA
4.3
V
V
V
4
10
µs
0.7
2.1
SMBus Frequency
SMBus Free Time
%
V
48
VALS On-Resistance
TFLT Charge Current
kHz
9.7
MAX8759 is enabled, 6V < VBATT < 28V,
ILOAD = 1mA
DEL Disable Threshold
50
PWMI duty cycle = 0%
VALS Output Voltage
Maximum Zero-Crossing Delay
V
PWMI duty cycle = 50%
ALS Full-Adjustment Range
Zero-Crossing Delay
UNITS
0.7
2.1
PWMI Input Frequency Range
PWMI Brightness Setting
MAX
mA
100
kHz
4.7
µs
SCL Serial Clock High Period
tHIGH
4
µs
SCL Serial Clock Low Period
tLOW
4.7
µs
START Condition Setup Time
tSU:STA
4.7
µs
START Condition Hold Time
tHD:STA
4
µs
STOP Condition Setup Time from SCL
tSU:STO
4
µs
SDA Valid to SCL Rising-Edge Setup Time,
Slave Clocking in Data
tSU:DAT
250
ns
SCL Falling Edge to SDA Transition
tHD:DAT
0
ns
SCL Falling Edge to SDA Valid,
Reading Out Data
tDV
200
ns
Note 1: Specifications to -40°C are guaranteed by design, not production tested.
6
_______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
HIGH-INPUT VOLTAGE OPERATION
(VIN = 20.0V)
LOW-INPUT VOLTAGE OPERATION
(VIN = 8.0V)
MAX8759 toc03
A
A
B
B
C
C
C
D
D
D
A
B
10µs/div
10µs/div
LINE TRANSIENT RESPONSE
(20V TO 8V)
100µs/div
C: LX2, 20V/div
D: IFB, 2V/div
A: VFB, 2V/div
B: LX1, 20V/div
C: LX2, 10V/div
D:IFB, 2V/div
A: VFB, 2V/div
B: LX1, 10V/div
LINE TRANSIENT RESPONSE
(8V TO 20V)
MAX8759 toc02
MAX8759 toc01
MINIMUM BRIGHTNESS STARTUP WAVEFORM
(SMBus MODE, BRIGHTNESS REGISTER = 0x00)
MAX8759 toc04
C: IFB, 2V/div
D: LX1, 20V/div
A: VIN, 10V/div
B: COMP, 2V/div
MINIMUM BRIGHTNESS DPWM OPERATION
(SMBus MODE, BRIGHTNESS REGISTER = 0x00)
MAX8759 toc06
MAX8759 toc05
A
A
A
B
B
B
C
C
C
D
100µs/div
2ms/div
2ms/div
C: IFB, 2V/div
D: LX1, 20V/div
A: VIN, 10V/div
B: COMP, 2V/div
50% BRIGHTNESS DPWM OPERATION
(SMBus MODE, BRIGHTNESS REGISTER = 0x80)
DPWM SOFT-START
DPWM SOFT-STOP
MAX8759 toc08
MAX8759 toc07
C: IFB, 2V/div
A: VFB, 2V/div
B: COMP, 1V/div
C: IFB, 2V/div
A: VFB, 2V/div
B: COMP, 1V/div
MAX8759 toc09
A
A
A
B
B
B
C
C
C
40µs/div
2ms/div
A: VFB, 2V/div
B: COMP, 1V/div
C: IFB, 2V/div
A: VFB, 2V/div
B: COMP, 1V/div
40µs/div
C: IFB, 2V/div
A: VFB, 2V/div
B: COMP, 1V/div
C: IFB, 2V/div
_______________________________________________________________________________________
7
MAX8759
Typical Operating Characteristics
(Circuit of Figure 1, VIN = 12V, VCC = VDD, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VIN = 12V, VCC = VDD, TA = +25°C, unless otherwise noted.)
SWITCHING FREQUENCY
vs. INPUT VOLTAGE
SECONDARY SHORT-CIRCUIT PROTECTION
AND TIMEOUT
MAX8759 toc011
80
A
A
B
B
SWITCHING FREQUENCY (kHz)
MAX8759 toc010
C
C
MAX8759 toc12
OPEN-LAMP VOLTAGE
LIMITING AND TIMEOUT
70
60
50
40
30
RMS LAMP CURRENT (mA)
250
200
150
7
ILAMP = 6mA
6
ILAMP = 5mA
5
ILAMP = 4mA
6.2
6.1
4
100
50
100
150
200
250
300
350
5.9
5.8
5.6
5
10
15
20
5
25
10
15
20
25
RFREQ (kΩ)
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
NORMALIZED BRIGHTNESS
vs. SMBus BRIGHTNESS SETTING
NORMALIZED BRIGHTNESS
vs. PWMI DUTY CYCLE
NORMALIZED BRIGHTNESS
vs. ALS VOLTAGE
40
20
60
40
20
20
40
60
BRIGHTNESS SETTING (%)
80
100
80
60
40
20
0
0
0
MAX8759 toc18
80
100
NORMALIZED BRIGHTNESS (%)
60
MAX8759 toc17
80
100
NORMALIZED BRIGHTNESS (%)
MAX8759 toc16
100
0
6.0
5.7
3
50
25
MAX8759 toc15
ILAMP = 7mA
RMS LAMP CURRENT (mA)
MAX8759 toc13
300
DPWM FREQUENCY (Hz)
8
20
RMS LAMP CURRENT (ILAMP = 6mA)
vs. INPUT VOLTAGE
RMS LAMP CURRENT
vs. INPUT VOLTAGE
350
15
VIN (V)
MAX8759 toc14
DPWM FREQUENCY
vs. RFREQ
10
C: TFLT, 1V/div
A: ISEC, 2V/div
B: COMP, 1V/div
C: TFLT, 5V/div
A: VFB, 2V/div
B: COMP, 500mV/div
8
5
2ms/div
200ms/div
NORMALIZED BRIGHTNESS (%)
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
0
0.2
0.4
0.6
PWMI DUTY RATIO
0.8
1.0
0
0.4
0.8
1.2
VALS (V)
_______________________________________________________________________________________
1.6
2.0
Low-Cost, SMBus, CCFL Backlight Controller
NORMALIZED BRIGHTNESS
vs. SMBus BRIGHTNESS AND PWMI DUTY CYCLE
SMB = 0xFF
MAX8759 toc20
80
1.0
MAX8759 toc19
0.8
VALS = 1.8V
VALS = 1.8V
NORMALIZED BRIGHTNESS (%)
100
NORMALIZED BRIGHTNESS
vs. ALS VOLTAGE AND PWMI DUTY CYCLE
60
40
20
0.6
0.4
0.2
SMB = 0x80
0
VALS = 0.8V
0
0
0.2
0.4
0.6
0.8
1.0
0
0.2
0.4
PWMI DUTY RATIO
0.6
0.8
1.0
PWMI DUTY RATIO
ALS TRANSIENT RESPONSE
(ALSDEL1 = ALSDEL0 = 0)
VCC LINE REGULATION
MAX8759 toc21
MAX8759 toc22
5.35
VCC VOLTAGE (V)
5.34
A
5.33
5.32
5.31
B
5.30
1s/div
A: ALS, 1V/div
8
12
B: COMP, 1V/div
5.33
5.32
VIN = 12V
MAX8759 toc24
VIN = 24V
5.31
VCC VOLTAGE (V)
VCC VOLTAGE (V)
24
5.32
MAX8759 toc23
5.35
5.31
20
VCC VOLTAGE
vs. TEMPERATURE
VCC LOAD REGULATION
5.34
16
INPUT VOLTAGE (V)
5.30
5.29
5.28
5.30
5.27
0
2
4
6
8
LOAD CURRENT (mA)
10
12
-40
-20
0
20
40
60
80
TEMPERATURE (°C)
_______________________________________________________________________________________
9
MAX8759
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VIN = 12V, VCC = VDD, TA = +25°C, unless otherwise noted.)
Low-Cost, SMBus, CCFL Backlight Controller
MAX8759
Pin Description
PIN
NAME
1
BATT
Supply Input. BATT is the input to the internal 5.35V linear regulator that powers the device. Bypass BATT
to GND with a 0.1µF ceramic capacitor.
2
SDA
SMBus Serial Data Input
3
SCL
SMBus Serial Clock Input
4
TFLT
Fault-Timer Adjustment Pin. Connect a capacitor from TFLT to GND to set the time-out periods for openlamp and secondary overcurrent faults.
5
VALS
Ambient-Light-Sensor Supply Pin. Bypass VALS to GND with a 0.1µF capacitor.
6
ALS
7
PWMI
DPST Control Input
8
PWMO
DPST Buffer Output. Connect a capacitor between PWMO and GND. The capacitor forms a lowpass filter
with an internal 40kΩ (typ) resistor for filtering the DPST signal.
9
FREQ
Chopping-Frequency Adjustment Pin. Connect a resistor from FREQ to GND to set the DPWM frequency:
fDPWM = 210Hz × 169kΩ / RFREQ.
10
COMP
Transconductance Error Amplifier Output. A compensation capacitor connected between COMP and GND
sets the rise and fall time of the lamp-current envelope in DPWM operation.
11
DEL
Adaptive Zero-Crossing-Delay Adjustment Pin. Connect a resistor between DEL and GND to adjust the
range of the zero-crossing delay. Connecting DEL to VCC disables the zero-crossing delay function.
IFB1
Lamp-Current-Feedback Input. The IFB1 sense signal is internally full-wave rectified. IFB1 is compared
with IFB2 and the larger is used for lamp-current regulation. The average value of the rectified signal is
regulated to 785mV (typ) by controlling the on-time of high-side switch. An open-lamp fault is generated if
the peak voltage of IFB1 is below 600mV for a fault delay period set by TFLT.
IFB2
Lamp-Current-Feedback Input. The IFB2 sense signal is internally full-wave rectified. IFB1 is compared
with IFB2 and the larger is used for lamp-current regulation. The average value of the rectified signal is
regulated to 800mV (typ) by controlling the on-time of high-side switch. An open-lamp fault is generated if
the peak voltage of IFB2 is below 600mV for a fault-delay period set by TFLT. IFB2 input can be disabled
by connecting IFB2 to VCC.
VFB
Transformer Secondary Voltage-Feedback Input. A capacitive voltage-divider between the high-voltage
terminal of the CCFL tube and GND sets the maximum average lamp voltage during striking and lamp-out
fault. When the peak voltage on VFB exceeds the internal overvoltage threshold, the controller turns on an
internal current sink, discharging the COMP capacitor to limit the switch on-time. The VFB pin is also used
to detect a secondary undervoltage condition. If the peak voltage on VFB is below 230mV continuously for
250µs during the DPWM ON period, the MAX8759 shuts down.
15
ISEC
Transformer Secondary Current-Feedback Input. A current-sense resistor connected between the lowvoltage end of the transformer secondary and the ground sets the maximum secondary current during
short-circuit fault. When the peak voltage on ISEC exceeds the internal overcurrent threshold, the
controller turns on an internal current sink discharging the COMP capacitor.
16
LX1
GH1 Gate-Driver Return. LX1 is the input to the current-limit and zero-crossing comparators. The device
senses the voltage across the low-side MOSFET NL1 to detect primary current zero crossing and primary
overcurrent.
17
GH1
High-Side MOSFET NH1 Gate Driver Output
12
13
14
10
FUNCTION
Ambient-Light-Sensor Input
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
PIN
NAME
18
BST1
FUNCTION
19
PGND1
20
GL1
Low-Side MOSFET NL1 Gate Driver Output
21
VDD
Low-Side Gate-Driver Supply Input. Connect VDD to the output of the internal linear regulator (VCC).
22
GL2
Low-Side MOSFET NL2 Gate-Driver Output
23
PGND2
24
BST2
GH2 Gate-Driver Supply Input. Connect a 0.1µF capacitor from LX2 to BST2.
25
GH2
High-Side MOSFET NH2 Gate-Driver Output
26
LX2
GH2 Gate-Driver Return. LX2 is the input to the current-limit and zero-crossing comparators. The device
senses the voltage across the low-side MOSFET NL2 to detect primary current zero crossing and primary
overcurrent.
27
GND
Analog Ground. The ground return for VCC, REF, and other analog circuitry. Connect GND to PGND under
the IC at the IC’s backside exposed metal pad.
28
VCC
5.35V/10mA Internal Linear-Regulator Output. VCC is the supply voltage for the device. Bypass VCC with a
0.47µF ceramic capacitor to GND.
—
EP
GH1 Gate-Driver Supply Input. Connect a 0.1µF capacitor from LX1 to BST1.
Power Ground. PGND1 is the return for the GL1 gate driver.
Power Ground. PGND2 is the return for the GL2 gate driver.
Exposed Backside Pad. Connect PAD to GND.
______________________________________________________________________________________
11
MAX8759
Pin Description (continued)
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
INPUT VOLTAGE
F1
7.5V TO 24V
2A
21
C7
0.1µF
27
11
BATT
VDD
C8
0.47µF
GND
BST2
DEL
BST1
28
VCC
VCC
GH1
2
3
MAX8759
LX1
7
8
PGND1
N1A
N1B
C3
2.2µF
PGND2
9
FREQ
R3
169kΩ
1%
GH2
IFB1
IFB2
5
VALS
VFB
C15
0.1µF
ISEC
6
16
26
C11
0.1µF
20
N2A
N2B
19
T1
1:110
FDC6561AN
C4
10pF
3kV
PWMO
GL2
ALS OUTPUT
17
PWMI
C12
1µF
ALS SUPPLY
C2
2.2µF
FDC6561AN
SCL
GL1
PWM INPUT
18
SDA
LX2
SMB_CLOCK
24
C10
0.1µF
C9
0.47µF
SMB_DATA
C1
10µF
25V
21
ALS
COMP
TFLT
CCFL
23
22
25
12
13
VCC
14
15
C6
68nF
10
4
R2
3.9kΩ
C13
6.8nF
C14
0.22µF
Figure 1. Typical MAX8759 Single-Lamp Operating Circuit
12
______________________________________________________________________________________
C5
10nF
R1
150Ω
1%
Low-Cost, SMBus, CCFL Backlight Controller
The MAX8759 typical operating circuit (Figure 1) is a
single-lamp CCFL backlight inverter for notebook computer TFT LCD panels. The input voltage range of the
circuit is from 7.5V to 24V. The maximum RMS lamp
current is set to 6mA and the maximum RMS striking
voltage is set to 1800V. Table 1 lists some important
components and Table 2 lists the component suppliers’
contact information.
Detailed Description
The MAX8759 controls a full-bridge resonant inverter to
convert an unregulated DC input into a high-frequency
AC output for powering CCFLs. The resonant operation
maximizes striking capability and provides near-sinu-
soidal waveforms over the entire input range to improve
CCFL lifetime. The lamp brightness is adjusted by turning the lamp on and off with a DPWM signal. The
DPWM frequency can be accurately adjusted with a
resistor. The brightness of the lamp is proportional to
the duty cycle of the DPWM signal, which is controlled
either with a 2-wire SMBus-compatible interface, with
an external ALS, or with an external PWM signal. The
device also includes safety features that effectively protect against single-point fault conditions such as lampout and secondary short-circuit faults. An internal 5.35V
linear regulator powers the MOSFET drivers and most
of the internal circuitry. Figure 2 is the functional diagram of the MAX8759 and Figure 3 is the detailed diagram of the SMBus and ALS input block.
Resonant Operation
Table 1. List of Important Components
DESIGNATION
C1
C2, C3
DESCRIPTION
10µF ±20%, 25V X5R ceramic capacitor
(1210)
Murata GRM32DR61E106M
TDK C3225X5R1E106M
2.2µF ±10%, 25V X5R ceramic capacitors
(0805)
Murata GRM21BR61E225K
TDK C2012X5R1E225K
C4
10pF ±10%, 3kV HV ceramic capacitor
(1808)
Kemet C1808C100KHGAC
TDK C4520C0G3F100F
NH1/2, NL1/2
Dual n-channel MOSFETs, 30V, 0.095Ω,
6-pin SOT23
Fairchild FDC6561AN
T1
CCFL transformer, 1:110 turns ratio
TMP UI9.8L type
Table 2. Component Suppliers
SUPPLIER
WEBSITE
Fairchild
Semiconductor
www.fairchildsemi.com
Kemet
www.kemet.com
Murata
www.murata.com
TDK
www.components.tdk.com
TMP
www.tmp.com
The MAX8759 drives four n-channel power MOSFETs
that make up the zero-voltage-switching (ZVS) fullbridge inverter as shown in Figure 4. Assume that NH1
and NL2 are on at the beginning of a switching cycle
as shown in Figure 4(a). The primary current flows
through MOSFET NH1, DC blocking capacitor C2, the
primary side of transformer T1, and MOSFET NL2.
During this interval, the primary current ramps up until
the controller turns off NH1. When NH1 is turned off, the
primary current forward biases the body diode of NL1,
which clamps the LX1 voltage just below ground as
shown in Figure 4(b). When the controller turns on NL1,
its drain-to-source voltage is near zero because its forward-biased body diode clamps the drain. Since NL2
is still on, the primary current flows through NL1, C2,
the primary side of T1, and NL2. Once the primary current drops to the minimum current threshold
(6mV/R DS(ON) ), the controller turns off NL2. The
remaining energy in T1 charges up the LX2 node until
the body diode of NH2 is forward biased. When NH2
turns on, it does so with near-zero drain-to-source voltage. The primary current reverses polarity as shown in
Figure 4(c), beginning a new cycle with the current
flowing in the opposite direction, with NH2 and NL1 on.
The primary current ramps up until the controller turns
off NH2. When NH2 is turned off, the primary current
forward biases the body diode of NL2, which clamps
the LX2 voltage just below ground as shown in Figure
4(d). After the LX2 node goes low, the controller losslessly turns on NL2. Once the primary current drops to
the minimum current threshold, the controller turns off
NL1. The remaining energy charges up the LX1 node
until the body diode of NH1 is forward biased. Finally,
NH1 losslessly turns on, beginning a new cycle as
shown in Figure 4(a). Note that switching transitions on
all four power MOSFETs occur under ZVS conditions,
which reduces transient power losses and EMI.
______________________________________________________________________________________
13
MAX8759
Typical Operating Circuit
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
LINEAR
REGULATOR
BATT
BIAS EN
GND
RDY
UVLO
COMPARATOR
4.3V
VCC
MAX8759
VCC
RDY
VALS
OC
COMP
ISEC
OC
S
Q
1.21V
ZX
FAULT
LATCH
OPEN-LAMP
COMP
MIN
TFLT
135µA
R
1µA
FW
VFB
FW
MAX
VREF
BATT
Q
SHUTDOWN
R
230mV
600mV
IFB1
IFB2
S
4V
UV
COMP
ERROR
AMP
BST1
COMP
1000µA
100µA
DH
LX1
OC
VFB
BST2
2.3V
OV
COMP
DWPM
OSC
FREQ
MIN
TON
PWM
COMP
8-BIT
COUNTER
SCL
SMBus
S
ALS
PWMI
R
GATE-DRIVER
CONTROL
STATE
MACHINE
Q
R
TON FF
S
Q
DPWM
LATCH
SDA
GH2
LX2
VDD
DL
GL1
PGND2
ALS
ADC
BRIGHTNESS
CONTROL
ZERO-CROSS
ZX DETECTIONS
AND
DELAY BLOCK
DPWM
COMP
PWM
ADC
DL
LX_
GL2
PGND1
MUX
ILIM
COMP
400mV
Figure 2. MAX8759 Functional Diagram
14
DH
Q
40kΩ
PWMO
GH1
______________________________________________________________________________________
DEL
Low-Cost, SMBus, CCFL Backlight Controller
MAX8759
PWMO
BUFFER
A
PWMI
D
MUX
"1"
PWM_MD
DIGITAL
MULTIPLIER
BUFFER
MUX
DPWM
SETTING
ALS
A
DIGITAL
POT
D
PWM_SEL
ALS
CLAMP
OFFSET
MUX
ALS_CTL
FAULT/
STATUS
REGISTER
0X02
SDA
SCL
ALS
STATUS
REGISTER
0X04
ALS
LOW-LIMIT
REGISTER
0X05
ALS
HIGH-LIMIT
REGISTER
0X06
BRIGHT
CONTROL
REGISTER
0X00
DEVICE
CONTROL
REGISTER
INVERTER
ON/OFF
0X01
SMBus AND AMBIENT-LIGHT-SENSOR INPUT BLOCK
SMBus
INTERFACE
Figure 3. MAX8759 SMBus and Ambient-Light-Sensor Input Block
A simplified CCFL inverter circuit is shown in Figure 5
(a). The full-bridge power stage is simplified and represented as a square-wave AC source. The resonant tank
circuit can be further simplified to Figure 5(b) by
removing the transformer. C S is the primary series
capacitor, CS’ is the series capacitance reflected to the
secondary, CP is the secondary parallel capacitor, N is
the transformer turns ratio, L is the transformer secondary leakage inductance, and R L is an idealized
resistance that models the CCFL in normal operation.
Figure 6 shows the frequency response of the resonant
tank’s voltage gain under different load conditions. The
primary series capacitor is 1µF, the secondary parallel
capacitor is 15pF, the transformer turns ratio is 1:93,
and the secondary leakage inductance is 260mH.
Notice that there are two peaks, fS, and fP, in the frequency response. The first peak fS is the series resonant peak determined by the secondary leakage
inductance (L) and the series capacitor reflected to the
secondary (C’S):
fS =
1
2π LCS
′
______________________________________________________________________________________
15
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
VBATT
VBATT
NH1
ON
NH2
OFF
NH1
OFF
NH2
ON
T1
T1
C2
C2
LX1
LX2
NL1
OFF
LX1
NL2
ON
LX2
NL1
ON
NL2
OFF
(a)
(c)
VBATT
VBATT
NH1
OFF
NH2
OFF
NH1
OFF
NH2
OFF
T1
T1
C2
C2
LX1
LX2
NL1
ON
LX1
NL2
ON
LX2
NL1
ON
NL2
ON
(BODY DIODE TURNS ON FIRST)
(BODY DIODE TURNS ON FIRST)
(b)
(d)
Figure 4. Resonant Operation
The second peak fP is the parallel resonant peak determined by the secondary leakage inductance (L), the
parallel capacitor (CP), and the series capacitor reflected to the secondary (C’S):
1
fP =
2π L
CS′ CP
CS′ + CP
The inverter is designed to operate between these two
resonant peaks. When the lamp is off, the operating
point of the resonant tank is close to the parallel resonant peak due to the lamp’s infinite impedance. The circuit displays the characteristics of a parallel-loaded
16
resonant converter. While in parallel-loaded resonant
operation, the inverter behaves like a voltage source to
generate the necessary striking voltage. Theoretically,
the output voltage of the resonant converter increases
until the lamp is ionized or until it reaches the IC’s secondary voltage limit. Once the lamp is ionized, the
equivalent load resistance decreases rapidly and the
operating point moves toward the series resonant peak.
While in series resonant operation, the inverter behaves
like a current source.
Lamp-Current Regulation
The MAX8759 uses a lamp-current control loop to regulate the current delivered to the CCFL. The heart of the
control loop is a transconductance error amplifier. The
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
MAX8759
CS
L
1:N
4
AC
SOURCE
CCFL
VOLTAGE GAIN (V/V)
CP
(a)
C'S =
CS
N2
L
3
RL INCREASING
2
1
AC
SOURCE
CP
RL
0
0
20
40
60
80
100
FREQUENCY (kHz)
(b)
Figure 5. Equivalent Resonant Tank Circuit
Figure 6. Frequency Response of the Resonant Tank
AC lamp current is sensed with a resistor connected in
series with the low-voltage terminal of the lamp. The
MAX8759 has two lamp-current feedback inputs (IFB1
and IFB2) to support dual-lamp application. The voltages across the sense resistors are fed to the IFB1 and
IFB2 inputs and are internally full-wave rectified. The
transconductance error amplifier selects the higher one
of the two feedback signals and compares the rectified
voltage with an internal threshold to generate an error
current. The error current charges and discharges a
capacitor connected between COMP and ground to
create an error voltage (VCOMP). VCOMP is then compared with an internal ramp signal to set the high-side
MOSFET switch on-time (tON).
Feed-forward control is implemented by increasing the
internal voltage ramp rate for higher VBATT. This has
the effect of varying tON as a function of the input voltage while maintaining approximately the same signal
levels at VCOMP. Since the required voltage change
across the compensation capacitor is minimal, the controller’s response to input voltage changes is essentially
instantaneous.
Feed-Forward Control
The MAX8759 is designed to maintain tight control of
the lamp current under all transient conditions. The
feed-forward control instantaneously adjusts the ontime for changes in input voltage (VBATT). This feature
provides immunity to input-voltage variations and simplifies loop compensation over wide input-voltage
ranges. The feed-forward control also improves the line
regulation for short DPWM on-times and makes startup
transients less dependent on the input voltage.
Lamp Startup
A CCFL is a gas-discharge lamp that is normally driven in
the avalanche mode. To start ionization in a nonionized
lamp, the applied voltage (striking voltage) must be
increased to the level required for the start of avalanche.
At low temperatures, the striking voltage can be several
times the typical operating voltage.
Because of the MAX8759’s resonant topology, the striking
voltage is guaranteed. Before the lamp is ionized, the
lamp impedance is infinite. The transformer secondary
leakage inductance and the high-voltage parallel capacitor determine the unloaded resonant frequency. Since the
unloaded resonant circuit has a high Q, it can generate
very high voltage across the lamp.
______________________________________________________________________________________
17
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
Dimming Control
The MAX8759 controls the brightness of the CCFL by
“chopping” the lamp current on and off using a low-frequency (between 100Hz and 350Hz) DPWM signal.
The frequency of the internal DPWM oscillator is
adjustable through a resistor connected between the
FREQ pin and GND. The CCFL brightness is proportional to the DPWM duty cycle, which can be adjusted
from 10.15% to 100%.
In DPWM operation, the COMP voltage controls the
dynamics of the lamp-current envelope. At the beginning of the DPWM ON cycle, the average value of the
lamp-current feedback signal is below the regulation
point, so the transconductance error amplifier sources
current into the COMP capacitor. The switch on-time
(tON) gradually increases as VCOMP rises, which provides soft-start. At the end of the DPWM ON cycle, the
MAX8759 turns on a 110µA internal current source. The
current source linearly discharges the COMP capacitor,
gradually decreasing tON, and providing soft-stop.
The DPWM frequency can be set with an external resistor. Connect a resistor between FREQ and GND. The
DPWM frequency is given by the following equation:
fDPWM = 210Hz × 169kΩ / RFREQ
The adjustable range of the DPWM frequency is
between 100Hz and 350Hz (RFREQ is between 100kΩ
and 350kΩ).
The MAX8759 has three ways for brightness control.
The brightness can be controlled by a 2-wire serial
interface (SMBus), by an external PWM signal, or by an
external ambient-light sensor signal. There are five
operating modes, which can be selected by setting bits
1 to 3 in device control register 0x01 (see the SMBus
Register Definitions section for details).
ALS Mode
The MAX8759 can work with several types of ambientlight sensors. The ideal ambient-light sensors should
have a linear response to ambient light and should
have a spectral response equivalent to that of the
human eye. Ambient-light sensors must provide filtering
of low-frequency harmonics found in the electrical
spectrum of the many light sources. The ALS’s output
should be a DC analog voltage that is linearly proportional to the ambient luminance.
In ALS mode, the MAX8759 sets the brightness based
on the analog voltage on the ALS pin. The ALS pin is
connected to the output of an external ambient-light
sensor. The usable input-voltage range of the ALS pin
18
is 0 to 1.8V. The MAX8759 compares the ALS input
voltage against user-programmable low and high limits.
When the ALS input voltage is below the low limit, the
brightness is clamped to the ALS low limit. When the
ALS input voltage is above the high limit, the brightness is
clamped to the ALS high limit. If the minimum ALS setting
is below 10%, the brightness is clamped to 10%. Figure 7
shows the brightness change as a function of the ALS
voltage.
The ALS input voltage is sampled every DPWM period
and is loaded in ALS status register 0x04. The analog
voltage on the ALS pin is converted into an 8-bit digital
code. The total number of brightness levels is 256. One
step change results in a 0.391% change in the DPWM
duty cycle.
PWM Mode
In PWM mode, the MAX8759 sets the brightness based
on the duty cycle of the PWMI signal. The absolute minimum brightness is 10%. If the PWMI duty cycle is less
than 10%, the brightness stays at 10%. The frequency
range of the PWMI signal is between 5kHz and 50kHz
when the PWMO capacitor is 1µF.
SMBus Mode
In SMBus mode, the MAX8759 sets the brightness
based on the brightness control register (0x00). The
brightness control register contains 8 bits and supports
256 brightness levels. A setting of 0xFF for register
0x00 sets the inverter to the maximum brightness. A
setting of 0x00 for register 0x00 sets the inverter to the
minimum brightness (10%).
ALS with DPST Mode
In ALS with DPST mode, the MAX8759 sets the brightness based on the analog voltage on the ALS pin and
duty cycle at the PWMI pin. The MAX8759 lowers the
ALS brightness setting by an additional amount that is
proportional to the duty cycle of the PWMI signal. For
example, if the ALS brightness setting is 80% and the
duty cycle of PWMI signal is 60%, the resulting brightness setting is 80% x 60% = 48%.
SMBus with DPST Mode
In SMBus with DPST mode, the MAX8759 sets the
brightness based on the brightness control register
(0x00). The MAX8759 lowers the SMBus brightness setting by an additional amount that is proportional to the
duty cycle of the PWMI signal. For example, if the
brightness control register is set to 0x80 (corresponding to 50% brightness setting) and the duty cycle of the
PWMI signal is 60%, the resulting brightness setting is
50% x 60% = 30%.
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
Lamp-Out Protection
For safety, the MAX8759 monitors the lamp-current
feedback inputs (IFB1 and IFB2) to detect faulty or
open CCFL tubes. As described in the Lamp-Current
Regulation section, the voltage on IFB1 and IFB2 is
internally full-wave rectified. If the rectified IFB1 or IFB2
voltage is below 600mV, the MAX8759 charges the
TFLT capacitor with 1µA. The MAX8759 sets the fault
latch and the device is shut down when the voltage on
TFLT exceeds 4V. Unlike the normal shutdown mode,
the linear regulator output (V CC ) remains at 5.35V.
Clearing bit 0 of the device control register (0x01) or
cycling the input power clears the fault latch.
During the fault-delay period, the current control loop
tries to maintain the lamp-current regulation by increasing the high-side MOSFET on-time. Because the lamp
impedance is very high when it is open, the transformer
secondary voltage rises as a result of the high Q-factor
of the resonant tank. Once the secondary voltage
exceeds the overvoltage threshold, the MAX8759 turns
on a 1000µA current source that discharges the COMP
capacitor. The on-time of the high-side MOSFET is
reduced, lowering the secondary voltage as the COMP
voltage decreases. Therefore, the peak voltage of the
transformer secondary winding never exceeds the limit
during the lamp-out delay period.
Primary Overcurrent Protection
The MAX8759 senses primary current in each switching cycle. When the regulator turns on the low-side
MOSFET, a comparator monitors the voltage drop from
LX_ to PGND_. If the voltage exceeds the current-limit
threshold (430mV, typ), the regulator immediately turns
off the high-side switch to prevent the transformer primary current from increasing further.
NORMALIZED BRIGHTNESS
1.0
0.8
Secondary Voltage Limiting (VFB)
The MAX8759 reduces the voltage stress on the transformer’s secondary winding by limiting the secondary
voltage during startup and open-lamp faults. The AC
voltage across the transformer secondary winding is
sensed through a capacitive voltage-divider formed by
C4 and C5 in Figure 1. The voltage across C5 is fed to
the VFB input. An overvoltage comparator compares
the VFB peak voltage with a 2.3V (typ) internal threshold. Once the VFB peak voltage exceeds the overvoltage threshold, the MAX8759 turns on an internal
1000µA current source that discharges the COMP
capacitor. The high-side MOSFET’s on-time shortens as
the COMP voltage decreases, limiting the transformer
secondary’s peak voltage at the threshold determined
by the capacitive voltage-divider.
Secondary Undervoltage Protection (VFB)
The MAX8759 senses the VFB voltage for undervoltage
condition. During the DPWM ON period, if the VFB voltage is below the undervoltage threshold (230mV, typ)
continuously for an internal delay period (250µs typ, for
RFREQ = 169kΩ), the MAX8759 shuts down.
Secondary Current Limit (ISEC)
The secondary current limit provides fail-safe current
limiting in case of a short circuit or leakage from the
lamp high-voltage terminal to ground that prevents the
current control loop from functioning properly. ISEC
monitors the voltage across a sense network placed
between the transformer’s low-voltage secondary terminal and ground. The ISEC voltage is continuously compared to the ISEC regulation threshold (1.21V, typ). Any
time the ISEC voltage exceeds the threshold, the
MAX8759 turns on a 1000µA current source that discharges the COMP capacitor, reducing the on-time of
the high-side switches. At the same time, the MAX8759
charges the TFLT capacitor with a 135µA current. The
MAX8759 sets the fault latch and shuts down when the
voltage on TFLT exceeds 4V. Clearing bit 0 of the
device control register (0x01) or cycling the input
power clears the fault latch.
Linear Regulator Output (VCC)
0.6
The internal linear regulator steps down the DC input
voltage at BATT pin to 5.35V (typ). The linear regulator
supplies power to the internal control circuitry of the
MAX8759 and is also used to power the MOSFET drivers by connecting VCC to VDD. The VCC voltage drops
to 4.5V in shutdown.
0.4
0.2
0
0
0.4
0.8
1.2
1.6
VALS (V)
Figure 7. Normalized Brightness vs. ALS Voltage
2.0
POR and UVLO
The MAX8759 includes power-on reset (POR) and
undervoltage lockout (UVLO) features. POR resets the
fault latch and sets all the SMBus registers to their POR
______________________________________________________________________________________
19
MAX8759
Fault Protections
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
WRITE-BYTE FORMAT
S
ADDRESS
WR
ACK
COMMAND
ACK
DATA
ACK
P
—
7 BITS
1b
1b
8 BITS
1b
8 BITS
1b
—
SLAVE ADDRESS
COMMAND BYTE: SELECTS
WHICH REGISTER YOU ARE
WRITING TO
READ-BYTE FORMAT
DATA BYTE: DATA GOES INTO THE
REGISTER SET BY THE COMMAND BYTE
S
ADDRESS
WR
ACK
COMMAND
ACK
S
ADDRESS
RD
ACK
DATA
///
P
—
7 BITS
1b
1b
8 BITS
1b
—
7 BITS
1b
1b
8 BITS
1b
—
SLAVE ADDRESS
COMMAND BYTE: SELECTS
WHICH REGISTER YOU ARE
READING FROM
SEND-BYTE FORMAT
SLAVE ADDRESS: REPEATED DATA BYTE: READS FROM THE
DUE TO CHANGE IN DATAREGISTER SET BY THE COMMAND
FLOW DIRECTION
BYTE
RECEIVE-BYTE FORMAT
S
ADDRESS
WR
ACK
COMMAND
ACK
P
S
ADDRESS
RD
ACK
DATA
///
P
—
7 BITS
1b
1b
8 BITS
1b
—
—
7 BITS
1b
1b
8 BITS
1b
—
COMMAND BYTE: SENDS COMMAND WITH NO DATA; USUALLY
USED FOR ONE-SHOT COMMAND
S = START CONDITION
P = STOP CONDITION
SHADED = SLAVE TRANSMISSION
ACK = ACKNOWLEDGED = 0
DATA BYTE: READS DATA FROM THE
REGISTER COMMANDED BY THE
LAST READ-BYTE OR WRITE-BYTE
TRANSMISSION; ALSO USED FOR
SMBus ALERT RESPONSE RETURN
ADDRESS
SLAVE ADDRESS
WR = WRITE = 0
RD = READ = 1
/// = NOT ACKNOWLEDGED = 1
Figure 8. SMBus Protocols
values. POR occurs when VCC rises above 1.75V (typ).
The UVLO occurs when VCC is below 4.2V (typ). The
MAX8759 disables both high-side and low-side switch
drivers below the UVLO threshold.
Low-Power Shutdown
The MAX8759 is placed into shutdown by clearing bit 0
of the device control register (0x01).When the
MAX8759 is shut down, all functions of the IC are
turned off except the 5.35V linear regulator. In shutdown, the linear regulator output voltage drops to 4.5V
and the supply current is 6µA (typ). While in shutdown,
the fault latch is reset. The device can be reenabled by
setting bit 0 of the device control register to 1.
Ambient-Light-Sensor Supply Pin (VALS)
The MAX8759 provides the supply voltage of the ALS
through the VALS pin. VALS is internally connected to
the 5.35V linear regulator output through a p-channel
MOSFET. The p-channel MOSFET is turned on when the
MAX8759 is enabled and turned off when the part is disabled. Bypass VALS to ground with a minimum 0.lµF
ceramic capacitor. Place the capacitor as close to the
ALS supply input as possible.
20
SMBus Interface (SDA, SCL)
The MAX8759 supports an SMBus-compatible 2-wire
digital interface. SDA is the bidirectional data line and
SCL is the clock line of the 2-wire interface corresponding respectively to SMBDATA and SMBCLK lines of the
SMBus. SDA and SCL have Schmidt-triggered inputs
that can accommodate slow edges; however, the rising
and falling edges should still be faster than 1µs and
300ns, respectively. The MAX8759 uses the write-byte
and read-byte protocols (Figure 8). The SMBus protocols are documented in System Management Bus
Specification V1.08 and are available at
http://www.sbs-forum.org/.
The MAX8759 is a slave-only device and responds to
the 7-bit address 0b0101100. The read and write commands can be distinguished by adding ONE more bit
(R/W bit) to the end of the 7-bit slave address, with one
indicating read and zero indicating write. The MAX8759
has seven registers: a brightness control register
(0x00), a device control register (0x01), a fault/status
register (0x02), an identification register (0x03), an ALS
status register (0x04), an ALS low-limit register (0x05),
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
tLOW
B
tHIGH
C
D
E
F
G
H
I
J
K
L
MAX8759
A
M
SMBCLK
SMBDATA
tSU:STA
tHD:STA
A = START CONDITION.
B = MSB OF ADDRESS CLOCKED INTO SLAVE.
C = LSB OF ADDRESS CLOCKED INTO SLAVE.
D = R/W BIT CLOCKED INTO SLAVE.
E = SLAVE PULLS SMBDATA LINE LOW .
tSU:DAT
tHD:DAT
tHD:DAT
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER.
G = MSB OF DATA CLOCKED INTO SLAVE.
H = LSB OF DATA CLOCKED INTO SLAVE.
I = SLAVE PULLS SMBDATA LINE LOW.
tSU:STO tBUF
J = ACKNOWLEDGE CLOCKED INTO MASTER.
K = ACKNOWLEDGE CLOCK PULSE.
L = STOP CONDITION, DATA EXECUTED BY SLAVE.
M = NEW START CONDITION .
Figure 9. SMBus Write Timing
and an ALS high-limit register (0x06). The MAX8759
only acknowledges these seven registers.
Communication starts with the master signaling the
beginning of a transmission with a START condition,
which is a high-to-low transition on SDA while SCL is
high. When the master has finished communicating
with the slave, the master issues a STOP condition,
which is a low-to-high transition on SDA while SCL is
high. The bus is then free for another transmission.
Figures 9 and 10 show the timing diagrams for signals
on the 2-wire interface. The address byte, command
byte, and data byte are transmitted between the START
and STOP conditions. The SDA state is allowed to
change only while SCL is low, except for the START
and STOP conditions. Data is transmitted in 8-bit words
and is sampled on the rising edge of SCL. Nine clock
cycles are required to transfer each byte in or out of the
MAX8759 since either the master or the slave acknowledges the receipt of the correct byte during the ninth
clock. If the MAX8759 receives its correct slave
address followed by R/W = 0, it expects to receive 1 or
2 bytes of information (depending on the protocol). If
the device detects a START or STOP condition prior to
clocking in the bytes of data, it considers this an error
condition and disregards all the data. If the transmission is completed correctly, the registers are updated
immediately after a STOP (or RESTART) condition. If
the MAX8759 receives its correct slave address followed by R/W = 1, it expects to clock out the register
data selected by the previous command byte.
SMBus Register Definitions
All MAX8759 registers are byte wide and accessible
through the read/write byte protocols mentioned in the
previous section. Their bit assignments are provided in
the following sections with reserved bits containing a
default value of zero.
Table 3 summarizes the register assignments, as well
as each register’s POR state. During shutdown, the serial interface remains fully functional.
______________________________________________________________________________________
21
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
A
B
tLOW
C
D
E
F
G
H
tHIGH
J
I
K
SMBCLK
SMBDATA
tSU:STA tHD:STA
tSU:DAT
A = START CONDITION.
B = MSB OF ADDRESS CLOCKED INTO SLAVE.
C = LSB OF ADDRESS CLOCKED INTO SLAVE.
D = R/W BIT CLOCKED INTO SLAVE.
tHD:DAT
tSU:STO
tSU:DAT
E = SLAVE PULLS SMBDATA LINE LOW.
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER.
G = MSB OF DATA CLOCKED INTO MASTER.
H = LSB OF DATA CLOCKED INTO MASTER.
tBUF
I = ACKNOWLEDGE CLOCK PULSE.
J = STOP CONDITION.
K = NEW START CONDITION.
Figure 10. SMBus Read Timing
Table 3. Commands Description
DATA-REGISTER BIT ASSIGNMENT
SMBus
COMMAND POR
PROTOCOL
BYTE
STATE
BIT 7
(MSB)
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
(LSB)
BR7
BRT6
BRT5
BR4
BRT3
BRT2
BRT1
BRT0
Read and
Write
0x00
0xFF
Read and
Write
0x01
0x00
Reserved Reserved
ALSDEL1 ALSDEL0
Read Only
0x02
N/A
Reserved Reserved
Reserved Reserved LAMP_STAT OV_CURR Reserved
Read Only
0x03
0x01
MFG4
MFG3
MFG2
MFG1
MFG0
REV2
REV1
REV0
Read Only
0x04
0x00
ALS7
ALS6
ALS5
ALS4
ALS3
ALS2
ALS1
ALS0
Read and
Write
0x05
0x00
ALSLL7
ALSLL6
ALSLL5
ALSLL4
ALSLL3
ALSLL2
ALSLL1
ALSLL0
Read and
Write
0x06
0xFF
ALSHL7
ALSHL6
ALSHL5
ALSHL4
ALSHL3
ALSHL2
ALSHL1
ALSHL0
22
ALS_CTL
PWM_MD PWM_SEL LAMP_CTL
______________________________________________________________________________________
FAULT
Low-Cost, SMBus, CCFL Backlight Controller
SMBus mode. A read-byte cycle to register 0x00
returns the current brightness level regardless of the
operation mode. A setting of 0xFF for register 0x00 sets
the inverter to the maximum brightness. A setting of
0x00 for register 0x00 sets the inverter to the minimum
brightness.
BIT 7 (R/W)
BIT 6 (R/W)
BIT 5 (R/W)
BIT 4 (R/W)
BIT 3 (R/W)
BIT 2 (R/W)
BIT 1 (R/W)
BIT 0 (R/W)
BRT7
BRT6
BRT5
BRT4
BRT3
BRT2
BRT1
BRT0
BRT[7..0]: 256 brightness levels.
Device Control Register [0x01] (POR = 0x00)
This register has a single bit that controls the inverter
ON/OFF state, 3 bits that control the operating mode of
the inverter, and 2 bits for setting ALS delay time. The
remaining bits are reserved for future use.
BIT 7
BIT 6
BIT 5 (R/W)
BIT 4 (R/W)
BIT 3 (R/W)
BIT 2 (R/W)
BIT 1 (R/W)
BIT 0 (R/W)
Reserved
Reserved
ALSDEL1
ALSDEL0
ALS_CTL
PWM_MD
PWM_SEL
LAMP_CTL
ALSDEL1: ALS delay select bit.
ALSDEL0: ALS delay select bit.
ALS_CTL: Ambient-light-sensor select bit (1 = use ALS, 0 = not use ALS).
PWM_MD: PWM mode select bit (1 = absolute brightness, 0 = percentage change).
PWM_SEL: Brightness control select bit (1 = control by PWM, 0 = control by SMBus).
LAMP_CTL: Inverter on/off bit (1 = on, 0 = off).
A value of 1 written to LAMP_CTL turns on the lamp as
quickly as possible. A value of zero written to LAMP_CTL
immediately turns off the lamp.
The PWM_SEL bit determines whether the SMBus or
PWM input should control brightness when the inverter is
not in ALS mode. This bit has no effect when ALS_CTL is
set to 1.
The PWM_MD bit selects the manner in which the PWM
input is to be interpreted. When this bit is zero, the PWM
input reflects a percentage change in the current brightness (i.e., DPST mode) and follows the following equation:
DPST brightness = BRTCURRENT × DPWM
where BRTCURRENT is the current brightness setting from
either ALS or SMBus without influence from the PWM
input and DPWM is the duty cycle of the PWM signal.
When PWM_MD bit is 1, the PWM input has no effect on
the brightness setting unless the inverter is in PWM mode.
When ALS_CTL is 1, the inverter controls brightness
based primarily on the light reading from the ALS.
However, the ALS brightness setting can be modified if
the PWM_MD bit is set to zero. When the ALS_CTL bit
is zero, the inverter controls the brightness according
to the PWM input (PWM mode), the SMBus setting
(SMBus mode), or a combination of the two (SMBus
mode with DPST).
______________________________________________________________________________________
23
MAX8759
Brightness Control Register [0x00]
(POR = 0xFF)
The brightness control register of the MAX8759 contains 8 bits and supports 256 brightness levels. A writebyte cycle to register 0x00 sets the brightness level if
the inverter is in SMBus mode. A write-byte cycle to
register 0x00 has no effect if the inverter is not in
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
The relationships among these 3 control bits can be
thought of as specifying an operating mode for the inverter. The defined modes are shown in Table 4. Note that
depending on the settings of some bits, other bits have
no effect and are don’t-care bits—they are shown with a
value of X in Table 4. For example, when the ALS_CTL bit
is 1, the value of PWM_SEL has no effect on the operation
of the inverter, so its value is shown as X.
ALSDEL0 and ALSDEL1 set the delay time required
to change the brightness in ALS mode. This delay time is
necessary for smooth transitions during brightness
change. Table 5 shows the available delays.
Note that the behavior of register 0x00 (brightness control register) is affected by certain combinations of the
control bits as shown in Table 4.
When SMBus mode is selected, register 0x00 reflects the
last value written to it. However, when any non-SMBus
mode is selected, register 0x00 reflects the current brightness value based on the current mode of operation.
Table 4. Operating Modes Selected by
Device Control Register Bits 3, 2, and 1
ALS_CTL
PWM_MD
PWM_SEL
MODE
1
1
X
ALS mode
1
0
X
ALS mode with DPST
0
X
1
PWM mode
0
1
0
SMBus mode
0
0
0
SMBus mode with
DPST
Table 5. Delay Time Selected by Device
Control Register Bits 5, 4
ALSDEL1
ALSDEL0
DELAY TIME
(ms)
N
PERIODS
1
1
25
5
1
0
15
3
Fault/Status Register [0x02] (POR = 0x00)
0
1
10
2
This register has 3 status bits that allow monitoring the
inverter’s operating state. Bit 0 is a logical OR of openlamp fault and overcurrent fault. Bit 2 indicates secondary/UL overcurrent fault. Bit 3 always indicates the
current lamp on/off status. The value of this bit is one
whenever both lamp 1 and lamp 2 are on. The value of
this bit is zero whenever lamp 1 or lamp 2 is off. The
0
0
20 (default)
4
remaining bits are reserved for future use. All reserved
bits return a zero when read. All the bits in this register
are read only. A write-byte cycle to register 0x02 has
no effect. Write zero to bit 0 of register 0x01 to clear the
fault bit.
BIT 7 (R)
BIT 6 (R)
BIT 5 (R)
BIT 4 (R)
BIT 3 (R)
BIT 2 (R)
BIT 1 (R)
BIT 0 (R)
Reserved
Reserved
Reserved
Reserved
LAMP_STAT
OV_CURR
Reserved
FAULT
LAMP_STAT: Lamp status bit (1 = lamp 1 and lamp 2 are on, 0 = lamp 1 or lamp 2 is off).
OV_CURR: Secondary/UL overcurrent fault (1 = secondary/UL overcurrent fault, 0 = no secondary/UL overcurrent).
FAULT: Fault bit (1 = open-lamp or primary overcurrent fault, 0 = no fault).
24
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
field widths allow up to 32 vendors with up to eight silicon revisions each. This register is read only. A writebyte cycle to register 0x03 has no effect.
BIT 7 (R)
BIT 6 (R)
BIT 5 (R)
BIT 4 (R)
BIT 3 (R)
BIT 2 (R)
BIT 1 (R)
BIT 0 (R)
MFG4
MFG3
MFG2
MFG1
MFG0
REV2
REV1
REV0
MFG[4..0]: Manufacturer ID (the vendor ID for Maxim is 0).
REV[2..0]: Silicon rev (revs 0–7 allowed for silicon revisions).
ALS Status Register [0x04] (POR = 0x00)
The ALS should return a value reflecting the brightness
setting based on the ALS input. The register has 8 bits
that define a full range of 256 brightness levels. The
register is read only and a write-byte cycle has no
effect. A read-byte cycle to register 0x04 returns the
current reading of ALS, regardless of the operating
mode set in register 0x01.
BIT 7 (R)
BIT 6 (R)
BIT 5 (R)
BIT 4 (R)
BIT 3 (R)
BIT 2 (R)
BIT 1 (R)
BIT 0 (R)
ALS7
ALS6
ALS5
ALS4
ALS3
ALS2
ALS1
ALS0
ALS[7..0]: 256 steps of ambient-light sensor reading.
ALS Low-Limit Register [0x05] (POR = 0x00)
The value in this read-write register reflects the lowest
possible brightness value the inverter can set based on
inputs from the ALS. Users can change this value so that
they can control the effect of ALS. A write-byte cycle to
register 0x05 sets the lowest possible brightness value
that can be set based on ALS inputs. If the brightness
setting due to ALS is lower than the value written to this
register, the inverter immediately increases the brightness setting to the newly written value. A read-byte cycle
to register 0x05 returns the current minimum brightness
value that can be set based on ALS inputs.
BIT 7 (R/W)
BIT 6 (R/W)
BIT 5 (R/W)
BIT 4 (R/W)
BIT 3 (R/W)
BIT 2 (R/W)
BIT 1 (R/W)
BIT 0 (R/W)
ALSLL7
ALSLL6
ALSLL5
ALSLL4
ALSLL3
ALSLL2
ALSLL1
ALSLL0
ALSLL[7..0]: The lowest brightness setting that can be set based on ALS inputs.
______________________________________________________________________________________
25
MAX8759
Identification Register [0x03] (POR = 0x01)
The identification register contains two bit fields to
denote the manufacturer and the silicon revision. The bit
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
ALS High-Limit Register [0x06] (POR = 0xFF)
The value in this read-write register reflects the highest
possible brightness value the inverter can set based on
inputs from the ALS. Users can change this value so
that they can control the effect of ALS. A write-byte
cycle to register 0x06 sets the highest possible brightness value that can be set based on ALS inputs. If the
brightness setting due to ALS is higher than the value
written to this register, the inverter immediately decreases the brightness setting to the newly written value. A
read-byte cycle to register 0x06 returns the current
maximum brightness value that can be set based on
ALS inputs. The default value of register 0x06 is 0xFF,
which corresponds to the maximum brightness.
BIT 7 (R/W)
BIT 6 (R/W)
BIT 5 (R/W)
BIT 4 (R/W)
BIT 3 (R/W)
BIT 2 (R/W)
BIT 1 (R/W)
BIT 0 (R/W)
ALSHL7
ALSHL6
ALSHL5
ALSHL4
ALSHL3
ALSHL2
ALSHL1
ALSHL0
ALSHL[7..0]: The highest brightness setting that can be set based on ALS inputs.
Applications Information
MOSFETs
The MAX8759 requires four external n-channel power
MOSFETs: NL1, NL2, NH1, and NH2 to form a fullbridge inverter circuit. The controller senses the on-state
drain-to-source voltage of the two low-side MOSFETs
NL1 and NL2 to detect the transformer primary current,
so the RDS(ON) of NL1 and NL2 should be matched. For
instance, if dual MOSFETs are used to form the full
bridge, NL1 and NL2 should be in one package. Since
the MAX8759 uses the low-side MOSFET RDS(ON) for
primary overcurrent protection, the lower the MOSFET
R DS(ON) , the higher the current limit. Therefore,
the user should select a dual logic-level n-channel
MOSFET with low RDS(ON) to minimize conduction loss,
and keep the primary current limit at a reasonable level.
The regulator uses ZVS to softly turn on each of four
switches in the full bridge. ZVS occurs when the external power MOSFETs are turned on when their respective drain-to-source voltages are near 0V (see the
Resonant Operation section). ZVS effectively eliminates
the instantaneous turn-on loss of MOSFETs caused by
C OSS (drain-to-source capacitance) and parasitic
capacitance discharge, and improves efficiency and
reduces switching-related EMI.
Setting the Lamp Current
The MAX8759 senses the lamp current flowing through
sense resistors connected between the low-voltage ter-
26
minals of the lamps and ground. The voltages across
the sense resistors are fed to IFB1 and IFB2 and are
internally full-wave rectified. The MAX8759 controls the
desired lamp current by regulating the average of the
rectified IFB_ voltages. To set the RMS lamp current in
a single-lamp application, determine the value of the
sense resistor as follows:
R1 =
π × 785mV
2 2 × ILAMP(RMS)
where ILAMP(RMS) is the desired RMS lamp current and
785mV is the typical value of the IFB1 regulation point
specified in the Electrical Characteristics table. To set
the RMS lamp current to 6mA, the value of the sense
resistor should be 148Ω. The closest standard 1%
resistors are 147Ω and 150Ω. The precise shape of the
lamp-current waveform, which is dependent on lamp
parasitics, influences the actual RMS lamp current. Use
a true RMS current meter to make final adjustments.
Setting the Secondary Voltage Limit
The MAX8759 limits the transformer secondary voltage
during startup and lamp-out faults. The secondary voltage is sensed through the capacitive voltage-divider
formed by C4 and C5 (Figure 1). The VFB voltage is
proportional to the CCFL voltage. The selection of the
parallel resonant capacitor C1 is described in the
Transformer Design and Resonant Component
Selection section. C4 is usually between 10pF and
22pF. After the value of C4 is determined, select C5
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
C5 =
2 × VLAMP(RMS)_ MAX
2.3V
× C4
where the 2.3V is the typical value of the VFB peak voltage when the lamp is open. To set the maximum RMS
secondary voltage to 1800V when C4 is 10pF, use
10nF for C5.
Setting the Secondary Current Limit
The MAX8759 limits the secondary current even if the
IFB_ sense resistors are shorted or transformer secondary current finds its way to ground without passing
through the sense resistors. ISEC monitors the peak voltage across the sense network (R2 and C6 in Figure 1)
connected between the low-voltage terminal of the transformer secondary winding and ground. Using an RCsense network instead of a single-sense resistor makes
the secondary current-limit frequency dependent. The UL
safety standard requires the AC peak current in a limitedcurrent circuit should not exceed 0.7mA for frequencies
below 1kHz. For frequencies above 1kHz, the limit of
0.7mA is multiplied by the value of the frequency in kilohertz but should not exceed 70mA peak when the frequency is equal to or above 100kHz. To meet the UL
current-limit specifications, determine the value of R2
using the current limit at 1kHz and determine the value of
C6 using the current limit at 100kHz:
R2 >
1.23V
0.7mA
where VLAMP(RMS) is the maximum RMS lamp voltage in
normal operation, and VIN(MIN) is the minimum DC input
voltage. If the maximum RMS lamp voltage in normal operation is 700V and the minimum DC input voltage is 7.5V,
the turns ratio should be greater than 104. The turns ratio of
the transformer used in the circuit of Figure 1 is 110.
The next step in the design procedure is to determine the
desired operating frequency range. The MAX8759 is synchronized to the natural resonant frequency of the resonant tank. The resonant frequency changes with
operating conditions, such as the input voltage, lamp
impedance, etc. Therefore, the switching frequency
varies over a certain range. To ensure reliable operation,
the resonant frequency range must be within the operating frequency range specified by the CCFL transformer
manufacturer. As discussed in the Resonant Operation
section, the resonant frequency range is determined by
transformer secondary leakage inductance L, the primary
series DC blocking capacitors (CS), and the secondary
parallel resonant capacitor CP. Since it is difficult to control the transformer leakage inductance, the resonant tank
design should be based on the existing secondary leakage inductance of the selected CCFL transformer. The
leakage inductance values can have large tolerance and
significant variations among different batches. It is best to
work directly with transformer vendors on leakage inductance requirements. The MAX8759 works best when the
secondary leakage inductance is between 250mH and
350mH. Series capacitor CS sets the minimum operating
frequency, which is approximately two times the series
resonant peak frequency. Choose:
= 1.75kΩ
70mA
C6 <
= 90nF
2π × 100kHz × 1.23V
where 1.23V is the typical value of the ISEC peak voltage when the transformer secondary is shorted. The
circuit of Figure 1 uses 3.9kΩ for R2 and 68nF for C6.
Transformer Design and Resonant
Component Selection
The transformer is the most important component of the
resonant tank circuit. The first step in designing the
transformer is to determine the transformer turns ratio.
The ratio must be high enough to support the CCFL
operating voltage at the minimum supply voltage. The
transformer turns ratio N can be calculated as follows:
VLAMP(RMS)
N≥
0.9 × VIN(MIN)
CS ≤
N2
π 2 × f 2 MIN × L
where fMIN is the minimum operating frequency range.
In the circuit of Figure 1, the transformer’s turns ratio is
110 and its secondary leakage inductance is approximately 300mH. To set the minimum operating frequency to 30kHz, the total series capacitance needs to be
less than 4.5µF. Therefore, two 2.2µF capacitors (C2
and C3) are used in Figure 1.
Parallel capacitor CP sets the maximum operating frequency, which is also the parallel resonant peak frequency. Choose:
CP ≥
CS
4 π 2 × f 2 MAX × L × CS − N2
In the circuit of Figure 1, to set the maximum operating
frequency to 100kHz, CP needs to be larger than 8.6pF.
A 10pF high-voltage capacitor (C4) is used in Figure 1.
______________________________________________________________________________________
27
MAX8759
using the following equation to set the desired maximum RMS secondary voltage VLAMP(RMS)_MAX:
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
The transformer core saturation should also be considered when selecting the operating frequency. The primary winding should have enough turns to prevent
transformer saturation under all operating conditions.
Use the following expression to calculate the minimum
number of turns N1 of the primary winding:
N1>
DMAX × VIN(MAX)
BS × S × fMIN
where DMAX is the maximum duty cycle (approximately
0.8) of the high-side switches, VIN(MAX) is the maximum
DC input voltage, BS is the saturation flux density of the
core, and S is the minimal cross-section area of the core.
COMP Capacitor Selection
The COMP capacitor sets the speed of the current loop
that is used during startup, maintaining lamp-current
regulation, and during transients caused by changing
the input voltage. To maintain stable operation, the
COMP capacitor (CCOMP) needs to be at least 3.3nF.
The COMP capacitor also limits the dynamics of the
lamp-current envelope in DPWM operation. At the end of
the DPWM on cycle, the MAX8759 turns on a 110µA
internal current source to linearly discharge the COMP
capacitor. Use the following equation to set the fall time:
CCOMP =
110µA × t FALL
VCOMP
where tFALL is the fall time of the lamp-current envelope
and VCOMP is the COMP voltage when the lamp current
is in regulation. At the beginning of the DPWM on cycle,
the COMP capacitor is charged by a transconductance
error amplifier. The rise time is about three times longer
than the fall time.
Setting the Fault-Delay Time
The TFLT capacitor determines the delay time for both
the open-lamp fault and secondary short-circuit fault.
The MAX8759 charges the TFLT capacitor with a 1µA
current source during an open-lamp fault and charges
the TFLT capacitor with a 135µA current source during
a secondary short-circuit fault. Therefore, the secondary short-circuit fault delay time is approximately
135 times shorter than that of open-lamp fault. The
MAX8759 sets the fault latch when the TFLT voltage
reaches 4V. Use the following equations to calculate
the open-lamp fault delay (T OPEN _ LAMP ) and secondary short-circuit fault delay (TSEC_SHORT):
TOPEN _ LAMP =
28
C TFLT × 4 V
1µA
TSEC _ SHORT =
C TFLT × 4 V
135µA
Bootstrap Capacitors
The high-side gate drivers are powered using two bootstrap circuits. The MAX8759 integrates the bootstrap
diodes so only two 0.1µF bootstrap capacitors are
needed. Connect the capacitors (C10 and C11 in
Figure 1) between LX1 and BST1, and between LX2
and BST2 to complete the bootstrap circuits.
Dual-Lamp Operating Circuit
The MAX8759 includes two lamp current feedback
input pins that support dual-lamp applications with a
minimum number of external components. Figure 11
shows the typical dual-lamp operating circuit.
Layout Guidelines
Careful PC board layout is important to achieve stable
operation. The high-voltage section and the switching
section of the circuit require particular attention. The
high-voltage sections of the layout need to be well separated from the control circuit. Most layouts for singlelamp notebook displays are constrained to long and
narrow form factors, so this separation occurs naturally.
Follow these guidelines for good PC board layout:
1) Keep the high-current paths short and wide, especially at the ground terminals. This is essential for
stable, jitter-free operation and high efficiency.
2) Use a star ground configuration for power and analog grounds. The power and analog grounds
should be completely isolated—meeting only at the
center of the star. The center should be placed at
the analog ground pin (GND). Using separate copper islands for these grounds can simplify this task.
Quiet analog ground is used for V CC , COMP,
FREQ, and TFLT.
3) Route high-speed switching nodes away from sensitive analog areas (VCC, COMP, FREQ, and TFLT).
Make all pin-strap control input connections to analog ground or VCC rather than power ground or VDD.
4) Mount the decoupling capacitor from VCC to GND
as close as possible to the IC with dedicated traces
that are not shared with other signal paths.
5) The current-sense paths for LX1 and LX2 to GND
must be made using Kelvin-sense connections to
guarantee the current-limit accuracy. With 8-pin SO
MOSFETs, this is best done by routing power to the
MOSFETs from outside, using the top copper layer,
while connecting GND and LX inside (underneath)
the 8-pin SO package.
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
F1
7.5V TO 21V
2A
VCC
1
C7
0.1µF
27
11
BATT
VDD
28
VCC
GND
BST2
DEL
VCC
GH1
C9
0.47µF
SMB_DATA
2
MAX8759
LX1
3
7
PWMO
C12
1µF
PGND2
GL2
GH2
9
FREQ
R3
169kΩ
1%
IFB1
IFB2
ISEC
ALS SUPPLY
5
FDS6990A
17
N1A
16
26
N1B
C2
2.2µF
C10
0.1µF
C11
0.1µF
1
2
C4
10pF
3kV
20
N2A
19
HV
LV
D3
N2B
FDS6990A
22
C3
2.2µF
C6
1nF
R14
100kΩ
T2
1:110
2
TFLT
LV
C5
10pF
3kV
13
R9
180kΩ
15
R12
180kΩ
COMP
HV
12
R10
20kΩ
VFB
R1
150Ω
1%
1
25
VALS
ALS
D4
R7
390kΩ
1%
23
C15
0.1µF
6
T1
1:110
PWMI
PGND1
8
18
SCL
GL1
PWM INPUT
24
SDA
LX2
SMB_CLOCK
C1
22µF
25V
21
C8
1µF
BST1
ALS OUTPUT
MAX8759
INPUT VOLTAGE
14
R8
390kΩ
1%
C17
1nF
R15
100kΩ
R2
150kΩ
1%
R13
20kΩ
10
4
C13
6.8nF
C14
0.22µF
Figure 11. Typical MAX8758 Dual-Lamp Operating Circuit
______________________________________________________________________________________
29
GH1
LX1
ISEC
TOP VIEW
BST1
Chip Information
PGND1
Pin Configuration
GL1
8) The traces to the capacitive voltage-divider on the
transformer’s secondary need to be widely separated
to prevent arcing. Moving these traces to opposite
sides of the board can be beneficial in some cases.
VDD
6) Ensure the feedback connections are short and
direct. To the extent possible, IFB1, IFB2, VFB, and
ISEC connections should be far away from the highvoltage traces and the transformer.
7) To the extent possible, high-voltage trace clearance
on the transformer’s secondary should be widely
separated. The high-voltage traces should also be
separated from adjacent ground planes to prevent
lossy capacitive coupling.
21
20
19
18
17
16
15
TRANSISTOR COUNT: 16,138
PROCESS: BiCMOS
GL2
22
14
VFB
PGND2
23
13
IFB2
BST2
24
12
IFB1
GH2
25
11
DEL
10
COMP
9
FREQ
8
PWMO
MAX8759
LX2
26
GND
27
1
2
3
4
5
6
7
SCL
TFLT
VALS
ALS
PWMI
28
SDA
VCC
*EXPOSED PADDLE
BATT
MAX8759
Low-Cost, SMBus, CCFL Backlight Controller
TQFN 5mm x 5mm
30
______________________________________________________________________________________
Low-Cost, SMBus, CCFL Backlight Controller
QFN THIN.EPS
D2
D
MARKING
b
CL
0.10 M C A B
D2/2
D/2
k
L
AAAAA
E/2
E2/2
CL
(NE-1) X e
E
DETAIL A
PIN # 1
I.D.
E2
PIN # 1 I.D.
0.35x45°
e/2
e
(ND-1) X e
DETAIL B
e
L1
L
CL
CL
L
L
e
e
0.10 C
A
C
0.08 C
A1 A3
PACKAGE OUTLINE,
16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm
-DRAWING NOT TO SCALE-
COMMON DIMENSIONS
A1
A3
b
D
E
e
PKG.
CODES
0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80
0
0.02 0.05
0
0.02 0.05
0
0.02 0.05
1
2
EXPOSED PAD VARIATIONS
PKG.
16L 5x5
20L 5x5
28L 5x5
32L 5x5
40L 5x5
SYMBOL MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX.
A
I
21-0140
0
0.02 0.05
0
T1655-2
T1655-3
T1655N-1
T2055-3
D2
3.00
3.00
3.00
3.00
3.00
T2055-4
T2055-5
3.15
T2855-3
3.15
T2855-4
2.60
T2855-5
2.60
3.15
T2855-6
T2855-7
2.60
T2855-8
3.15
T2855N-1 3.15
T3255-3
3.00
T3255-4
3.00
T3255-5
3.00
T3255N-1 3.00
T4055-1
3.20
0.02 0.05
0.20 REF.
0.20 REF.
0.20 REF.
0.20 REF.
0.20 REF.
0.25 0.30 0.35 0.25 0.30 0.35 0.20 0.25 0.30 0.20 0.25 0.30 0.15 0.20 0.25
4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10
4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10
0.80 BSC.
0.65 BSC.
0.50 BSC.
0.40 BSC.
0.50 BSC.
- 0.25 - 0.25 0.25 - 0.25 - 0.25 0.35 0.45
0.30 0.40 0.50 0.45 0.55 0.65 0.45 0.55 0.65 0.30 0.40 0.50 0.40 0.50 0.60
L1
- 0.30 0.40 0.50
16
40
N
20
28
32
ND
4
10
5
7
8
4
10
5
7
8
NE
WHHB
----WHHC
WHHD-1
WHHD-2
JEDEC
k
L
NOTES:
1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994.
2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES.
3. N IS THE TOTAL NUMBER OF TERMINALS.
L
E2
exceptions
MIN. NOM. MAX. MIN. NOM. MAX. ±0.15
3.10
3.10
3.10
3.10
3.10
3.25
3.25
2.70
2.70
3.25
2.70
3.25
3.25
3.10
3.10
3.10
3.10
3.30
3.20
3.20
3.20
3.20
3.20
3.35
3.35
2.80
2.80
3.35
2.80
3.35
3.35
3.20
3.20
3.20
3.20
3.40
3.00
3.00
3.00
3.00
3.00
3.15
3.15
2.60
2.60
3.15
2.60
3.15
3.15
33.00
33.00
3.00
3.00
3.20
3.10
3.10
3.10
3.10
3.10
3.25
3.25
2.70
2.70
3.25
2.70
3.25
3.25
3.10
3.10
3.10
3.10
3.30
3.20
3.20
3.20
3.20
3.20
3.35
3.35
2.80
2.80
3.35
2.80
3.35
3.35
3.20
3.20
3.20
3.20
3.40
**
**
**
**
**
0.40
**
**
**
**
**
0.40
**
**
**
**
**
**
DOWN
BONDS
ALLOWED
YES
NO
NO
YES
NO
YES
YES
YES
NO
NO
YES
YES
NO
YES
NO
YES
NO
YES
** SEE COMMON DIMENSIONS TABLE
4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL
CONFORM TO JESD 95-1 SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE
OPTIONAL, BUT MUST BE LOCATED WITHIN THE ZONE INDICATED. THE TERMINAL #1
IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE.
5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN
0.25 mm AND 0.30 mm FROM TERMINAL TIP.
6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY.
7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION.
8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
9. DRAWING CONFORMS TO JEDEC MO220, EXCEPT EXPOSED PAD DIMENSION FOR
T2855-3 AND T2855-6.
10. WARPAGE SHALL NOT EXCEED 0.10 mm.
11. MARKING IS FOR PACKAGE ORIENTATION REFERENCE ONLY.
12. NUMBER OF LEADS SHOWN ARE FOR REFERENCE ONLY.
13. LEAD CENTERLINES TO BE AT TRUE POSITION AS DEFINED BY BASIC DIMENSION "e", ±0.05.
PACKAGE OUTLINE,
16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm
21-0140
-DRAWING NOT TO SCALE-
I
2
2
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 31
© 2006 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products, Inc.
MAX8759
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)