PHILIPS UBA2071AT

UBA2071; UBA2071A
Half bridge control IC for CCFL backlighting
Rev. 01 — 23 June 2008
Product data sheet
1. General description
The UBA2071 and UBA2071A are high voltage ICs intended to drive Cold Cathode
Fluorescent Lamps (CCFLs) or External Electrode Fluorescent Lamps (EEFLs) for
backlighting applications. They can drive a half bridge circuit made up of two NMOSFETs
with a supply voltage of up to 550 V, so the inverter can be supplied directly from a 400 V
PFC bus.
The UBA2071 and UBA2071A contain a controller, a level shifter, a bootstrap diode and
drivers for the external half bridge power switches. It also contains a low frequency PWM
generator, which can be used to control the brightness level of the lamps, using an analog
brightness/dimming control voltage. PWM dimming can also be realized, using a digital
PWM input signal. PWM dimming can be synchronized with other ICs. The lamp current is
controlled by means of a true zero voltage switching resonant control principle, ensuring
lowest possible switch losses in the half bridge power structure.
The UBA2071 is designed to be supplied by a ∆V/∆t supply from the half bridge circuit that
it drives. The IC itself needs little current and if the IC is off, a clamp protects the supply
voltage from getting too high.
The UBA2071A is designed to be supplied by a fixed 12 V supply. It has a lower supply
start voltage and no supply clamp.
2. Features
n
n
n
n
n
n
n
n
n
n
n
n
n
Suitable for operating in a very wide inverter supply voltage range (up to 550 V DC).
Integrated level shifter.
Integrated bootstrap diode.
Lamp current control by means of a true zero voltage switching resonant control
principle.
Sample & Hold circuit, maintaining current control value during PWM lamp-off
situation.
Separately definable time constants for current control loop and PWM dimming
attack/decay setting.
Overvoltage control.
Overcurrent protection.
Ignition failure detection.
Hard switching control.
Arcing detection.
Open/short pin protections on feedback pins.
Integrated, programmable fault timer.
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
n Bidirectional pin acting both as fault signaling output and input, allowing external fault
interfacing to operate via the integrated fault timer.
n Brightness level adjustment through PWM dimming.
n Integrated PWM generator.
n Power-down mode.
n Communication pin for master / slave operation.
n DC blocking capacitor pre-charging sequence.
n Supply clamp (UBA2071 only).
3. Applications
n LCD-backlighting, including LCD-TV and LCD-monitor applications. The IC is intended
to drive and control a half bridge inverter with resonant load circuit for CCFLs, but can
also drive an array of External Electrode Fluorescent Lamps (EEFLs).
4. Quick reference data
Table 1.
Quick reference data.
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless
otherwise specified. All voltages are measured with respect to signal ground (SGND, pin 10). SGND
and PGND connected together. Currents are positive when flowing into the IC.
Symbol
Parameter
VSH
VVDD
IVDD
current on pin VDD
Min
Typ
Max
Unit
voltage on pin SH
-
-
550
V
voltage on pin VDD
-
-
14
V
EN pin grounded;
VVDD = 14.0 V;
UBA2071AT and
UBA2071ATS
-
-
0.22
mA
oscillating at fsw(min);
CCF = 100 pF
1.2
1.5
1.8
mA
disabled;
VVDD = 11 V
-
0.16
-
mA
oscillating;
CF = 100 pF;
GL and GH open
-
1.5
-
mA
CCF = 100 pF;
VPWMD = H;
VCSWP = 0 V
1.0
1.2
1.4
mA
10
-
100
kHz
38
40
42
kHz
fsw(max)/fsw(min) maximum switching
frequency to
minimum switching
frequency ratio
2.2
2.4
2.6
kHz
Vref(creg)
1.20
1.26
1.32
V
fsw(min)
minimum switching
frequency
Conditions
CCF = 100 pF
[1]
[2]
[1]
[2]
current regulation
reference voltage
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
2 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 1.
Quick reference data.
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless
otherwise specified. All voltages are measured with respect to signal ground (SGND, pin 10). SGND
and PGND connected together. Currents are positive when flowing into the IC.
Symbol
Parameter
Vth(ov)(VFB)
overvoltage
threshold voltage on
pin VFB
tto(fault)
fault time-out time
Isource(drv)
Conditions
Min
Typ
Max
Unit
2.40
2.50
2.60
V
CCT = 100 nF
0.85
1.00
1.15
s
driver source
current
VGL, VGH = 4 V;
VVDD = VFS = 12 V
−105
−90
−75
mA
Rsink(drv)
driver sink
resistance
VGL, VGH = 2 V;
VVDD = VFS = 12 V
13.5
16.0
18.5
Ω
fPWM
PWM frequency
[1]
75
-
1000
Hz
δPWMD
duty cycle on pin
PWMD
[3]
12
-
100
%
[1]
Given frequency is switching frequency of GL and GH. Sawtooth frequency on CF pin is twice as high.
[2]
Can be set by external capacitor
[3]
PWMD is active low: A low level on the PWMD pin corresponds with lamps-on. Example: δPWM = 20 %
means PWMD is during 20 % of each cycle low and the lamps are 20 % of the time on, resulting in a light
output of 20 %.
5. Ordering information
Table 2.
Ordering information
Type number
Package
Name
Description
Version
UBA2071T
SO24
plastic small outline package; 24 leads; body width 7.5 mm
SOT137-1
UBA2071AT
SO24
plastic small outline package; 24 leads; body width 7.5 mm
SOT137-1
UBA2071TS
SSOP24
plastic shrink small outline package; 24 leads;
body width 5.3 mm
SOT340-1
UBA2071ATS
SSOP24
plastic shrink small outline package; 24 leads;
body width 5.3 mm
SOT340-1
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
3 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
6. Block diagram
NONFAULT
CT
bootstrap diode
INTERNAL
SUPPLY
AND
REFERENCE
CIRCUITS
IREF
VDD
SGND
EN
VDD
FS
TIMER
LEVELSHIFTER
GH
high-side
driver
CONTROL
SH
NON-OVERLAP
TIMING
VDD
HF
OSCILLATOR
CF
CSWP
HARDSWITCHING
DETECTION
TRACK
AND
SWEEP
CVFB
GL
low-side
driver
PGND
MASTER / SLAVE
COMMUNICATION
VFB
COMM
OVERVOLTAGE
SENSING
ARCING
DETECTION
OVERCURRENT
DETECTION
PWM GENERATOR
IFB
DOUBLE
SIDE
RECTIFIER
LAMP
CURRENT
SENSING
UBA2071
CIFB PWMA PWMD CPWM
Fig 1.
014aaa098
Block diagram
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
4 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
7. Pinning information
7.1 Pinning
IFB
1
24 GH
CIFB
2
23 FS
VFB
3
22 SH
CVFB
4
21 n.c.
CSWP
5
20 n.c.
CT
6
CF
7
IREF
8
17 PGND
CPWM
9
16 VDD
UBA2071
19 n.c.
18 GL
SGND 10
15 EN
COMM 11
14 PWMA
NONFAULT 12
13 PWMD
014aaa099
Fig 2.
Pin assignment SO24 and SSOP24 package (top view)
7.2 Pin description
Table 3.
Pin description
Symbol
Pin
Description
Function
IFB
1
current feedback input.
Input signal for the lamp current control loop. Should be connected to a
voltage proportional to the lamp current.
CIFB
2
current regulation
capacitor.
A capacitor must be connected between this pin and the signal ground. It
sets the time constant of the lamp current control loop.
VFB
3
voltage feedback input
Input signal for the voltage control loop. Should be connected to a voltage
proportional to the transformer output voltage.
CVFB
4
voltage regulation
capacitor
A capacitor must be connected between this pin and the signal ground. It
sets the time constant of the voltage control loop.
CSWP
5
frequency sweep
capacitor
A capacitor must be connected between this pin and the signal ground. It
sets the time in which the HF frequency is swept up from regulation level to
the maximum frequency and back during PWM dimming.
CT
6
fault timing capacitor
A capacitor must be connected between this pin and the signal ground. It
sets the time that a fault condition is allowed before the IC shuts down itself.
CF
7
HF-oscillator timing
capacitor
A capacitor must be connected between this pin and the signal ground. It
sets the minimum switching frequency of the half bridge.
IREF
8
reference current output
A 33 kΩ resistor must be connected between this pin and the signal ground.
The IC uses it to make accurate internal currents.
CPWM
9
PWM timing capacitor
If a capacitor is connected between this pin and the signal ground, it sets the
frequency of the PWM oscillator.
If this pin is connected to signal ground the internal PWM oscillator is
disabled.
SGND
10
signal ground
COMM
11
master / slave
communication
Via this pin the IC can communicate with a dedicated slave device.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
5 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 3.
Symbol
Pin description …continued
Description
Function
NONFAULT 12
Pin
status signal
input/output
The IC signals a fault condition to external circuits by pulling this pin low. Also
external circuits can signal a fault condition to the IC by pulling this pin low.
PWMD
digital PWM dimming
input/output
Digital output of internally generated PWM signal if a capacitor is connected
to the CPWM pin.
13
Digital input of PWM signal if the CPWM pin is connected to signal ground.
Remark: The signal on the PWMD pin is active low, so low voltage on the
PWMD pin means lamps are on.
PWMA
14
analog PWM dimming
input
The duty cycle of the internally generated PWM signal is proportional to the
voltage on this pin.
EN
15
chip enable input
A low voltage on this pin will reset and shut down the IC. This pin is also used
to select between DC blocking capacitor charging mode and normal
operation.
VDD
16
supply input
A buffer capacitor must be connected between this pin and power ground.
PGND
17
power ground
return for the low-side driver.
GL
18
low-side driver output
Gate connection of the low-side power switch.
n.c.
19
not connected
HV spacer pin.
n.c.
20
not connected
HV spacer pin.
n.c.
21
not connected
HV spacer pin.
SH
22
high-side source
connection
Return for high side gate driver. Must be connected to the source of the
high-side half bridge power switch.
FS
23
floating supply
A buffer capacitor must be connected between this pin and the SH pin. This
capacitor is charged when the low-side power switch is on and supplies the
high-side driver when the high-side power switch is on.
GH
24
high-side driver output
Gate connection of the high-side half bridge power switch.
8. Functional description
The UBA2071 and UBA2071A are designed to drive a half bridge inverter (as shown in
Figure 3) with a resonant load. The load consists typically of a transformer with CCFLs or
EEFLs.
The IC has an AC lamp current sense input (IFB). It regulates the average absolute value
of the lamp current by varying its switching frequency. The load is presumed to be
inductive: higher frequency results in lower lamp current.
The UBA2071 and UBA2071A include a PWM dimming function. The ICs switch the
lamps on and off with a frequency lower than the lamp current frequency but higher than
what the human eye can see. The light output of the lamps can be set by setting the ratio
of the on-time and off-time.
These ICs have several forms of protection and the next chapters will describe each
function in more detail.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
6 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
VHV
UBA2071
FS
CFS
GH
VDD
SH
QHS
VHB
GL
LOAD
0.5 VHV
QLS
Cblock
PGND
014aaa100
Fig 3.
Basic half bridge inverter
8.1 Supply, Start-up and UnderVoltage LockOut (UVLO)
start
up
current
UBA2071
AUXILARY
SUPPLY
VDD
C1
014aaa101
Fig 4.
Supply configuration (for UBA2071 only)
The UBA2071 is supplied via the VDD pin as shown in Figure 4. The supply voltage is
either made by the inverter itself, using a ∆V/∆t or is a auxiliary fixed supply voltage. A
start-up current source that can supply minimal Istartup(VDD) is needed for start-up. This can
be a resistor to the half bridge supply voltage.
The IC starts up when the voltage at the VDD pin goes over Vstartup(VDD) and shuts down
when the voltage at the VDD pin drops below Vstop(VDD) and the output GL is high1. The
hysteresis between the start and stop levels allows the IC to be supplied by the supply
buffer capacitor (C1 in Figure 4) until the auxiliary supply is settled. The auxiliary supply
must not exceed the maximum voltage allowed on the VDD pin and has to be above
Vstop(VDD).
The UBA2071A can directly be supplied by a fixed voltage source on the VDD pin. The
voltage supplied by this source has to be above the maximum value of Vstartup(VDD) but
below the maximum of VVDD. Typically it will be a 12 V ± 5 % source.
1.
When both GH and GL are low, during the lamps-off period of PWM dimming (PWMD is high), the IC will shut down until the
PWMD is low and the GL is high again.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
7 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
8.2 VDD clamp
When the UBA2071 is disabled (EN pin low) or in the stop state, the VDD clamp is
activated. The VDD clamp is an internal active zener limiting the voltage to Vclamp(VDD). It
prevents the start-up current source from charging the VDD buffer capacitor to too high a
voltage.
The maximum current that is allowed to be delivered by the start-up current source is
determined by the clamp voltage as stated in Table 6 and the maximum allowed VDD
voltage as stated in Table 4.
The UBA2071A has no VDD clamp.
8.3 Enable
The UBA2071 or UBA2071A can be activated or set to standby via the EN pin. If the
voltage on the EN pin is below Vth(L)(EN), the IC will stop oscillating at the next GL high
state2, and most parts of the internal circuits will shut down. When the EN pin is left open,
it is pulled low by an internal bias current of Ibias(EN).
When the voltage on the EN pin comes above Vth(H)1(EN), the IC will start up in
DC blocking capacitor charging mode (see Section 8.8). When the voltage on the EN pin
goes over Vth(H)2(EN), the IC will start with the initial ignition frequency sweep (see
Section 8.8) and subsequently go to normal operation mode again.
8.4 The oscillator
The UBA2071 and UBA2071A have an internal voltage controlled sawtooth oscillator, see
Figure 5. Its frequency inverses in proportion to the capacitor connected to the CF pin.
The IC switches GL on and GH off during one oscillator period and GL off and GH on
during the next oscillator period. This results in a half bridge voltage with a frequency
(called the switching frequency fsw from here on) of half the oscillator frequency and with a
duty cycle of exactly 50 %.
The oscillator frequency is controlled by changing the charge current at the CF pin. By
changing the frequency the lamp current is controlled. It is also used to limit the
transformer output voltage and for gradually switching the lamps on and off during PWM
dimming.
2.
When both GH and GL are low during the lamps off period of PWM dimming (so PWMD is high), the IC will wait with entering the
standby state until PWMD becomes low again and GL can be made high.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
8 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
VCFH
VCF
0
t
VDD
VGH − VSH
0
t
VDD
VGL
0
t
VHV
VHB
0
t
tno
014aaa102
Fig 5.
Oscillator, driver and half bridge voltages
8.5 Non-overlap
During each transition between the two states GL high/GH low and GL low/GH high, GL
and GH will both be low for a fixed time tno (non-overlap time) to allow the half bridge point
to be charged or discharged by the load current (presuming the load always has an
inductive behavior), and thus enabling zero voltage switching, see Figure 5.
8.6 Low-side and high-side drivers
The low-side and high-side drivers are identical. The output of each driver is connected to
the equivalent gate of an external power MOSFET. The high-side driver is supplied by the
bootstrap capacitor, which is charged from the VDD voltage via an internal diode when the
low-side power MOSFETs is on. The low-side driver is directly supplied by the VDD
voltage.
8.7 DC blocking capacitor charging
When the IC is off, either because VVDD is too low, it is disabled via the EN pin, or it
stopped after the time-out period during a fault condition, the low-side power switch
(QLS in Figure 3) is turned on by making GL high. This ensures that the supply buffer
capacitor of the floating supply (CFS in Figure 3) is fully charged at start-up. As a side
effect the DC blocking capacitor (Cblock in Figure 3) will be completely discharged at
start-up. To prevent large inrush currents during the first switching cycles the UBA2071
and UBA2071A can first charge the DC blocking capacitor at start-up.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
9 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
When the voltage on the EN pin goes over Vth(H)1(EN) after the IC has been disabled (EN
pin below Vth(L)(EN)) the IC will start up in DC blocking capacitor charging mode3. When
the voltage on the EN pin goes over Vth(H)1(EN) after the IC has been off (EN pin below
Vth(L)(EN) or VDD below Vstop(VDD)) the IC will start up in DC blocking capacitor charging
mode. When the voltage on the EN pin goes over Vth(H)2(EN) the IC will continue with the
initial ignition frequency sweep and normal operation mode. Figure 6, EN configuration,
shows three examples of how the enable input can be used:
UBA2071
R1
EN
enable
C1
(1)
VHv
VHv
R2
UBA2071
R4
EN
R2
VCblock
UBA2071
R3
R4
EN
Cblock
Cblock
R3
R5
(2)
VCblock
disable
(3)
014aaa253
Fig 6.
EN configuration
1. Digital enable input with DC blocking capacitor charging. R1 and C1 define a fixed
DC blocking capacitor charging time.
Remark: The digital input signal high level has to be above the maximum value of
Vth(H)2(EN).
2. Sensing of HV supply and DC blocking capacitor voltages via the EN pin. The IC will
start in DC blocking capacitor charging mode if VVDD is above Vstartup(VDD) and VHV is
above ( ( R2/R4 ) + ( R2/R3 ) + 1 ) × V th(H)1(EN) . It will then go into initial ignition frequency
sweep and normal operation mode once VCblock has been charged to
( ( ( R4/R2 ) + ( R4/R3 ) + 1 ) × V th(H)2(EN) – R4/R2 × V HV ) .
3. Sensing of HV supply and DC blocking capacitor voltages via the EN pin combined
with digital enable input.
In DC blocking capacitor charging mode the low-side power switch (QLS in Figure 3) is
turned on for a period ((1/fsw(max)) − tno) and then the high-side power switch (QHS in
Figure 3) is turned on for a period ((1/fsw(max)) − tno) followed by a period of (3/fsw(min))
during which both power switches are off. This is repeated until the mode is left. When
leaving the DC blocking capacitor charging mode by raising the EN pin above Vth(H)2(EN),
the running cycle of the DC blocking capacitor charging mode will first be completed (see
Figure 7).
3.
When the enable input is kept high during the time that the IC is off, because the supply voltage is too low, the IC might not start in
DC blocking capacitor charging mode.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
10 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
(H)2(EN)
EN
(H)1(EN)
(L)(EN)
0
GH
GL
VSH
0
0.5 T
7.5 T
3 / fsw(min)
T
1 / fsw(max)
disabled
7.5 T
3 / fsw(min)
initial ignition sweep
and normal mode
DC blocking capacitor charging
014aaa252
Fig 7.
DC blocking capacitor charging mode
Remark: Due to the nature of the charging sequence, VCblock will automatically be
charged to 0.5 × VHV (when given enough time). If the IC is kept in DC blocking capacitor
charging mode longer than necessary, VCblock will remain 0.5 × VHV. Therefor the time
constant made by R1 and C1 in example A in Figure 6, is not critical. However, since
VCblock cannot become more than 0.5 × VHV, it is important to take a lower target value for
VCblock than 0.5 × VHV (with enough margin) in examples B and C of Figure 6, otherwise
the IC may get stuck in DC blocking capacitor charging mode.
8.8 Lamp (re-)ignition
The IC starts at its maximum switching frequency fsw(max). The lamp current and the lamp
voltage control loops are enabled. The frequency is swept down towards the minimum
frequency fsw(min), see Figure 9. During this initial ignition frequency sweep the lamp
voltage will increase as the frequency comes closer to the resonant frequency of the
unloaded resonance circuit. Once the ignition voltage Vign is reached the lamps will ignite
and the lamp voltage will drop4 to the voltage of the loaded resonance curve, see
Figure 8.
4.
For CCFLs only.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
11 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Vlamp
(V)
(1)
Vign
(2)
Vburn
fsw(min) freg fign
fsw(max)
f (kHz)
014aaa103
(1) Indicates lamp-OFF.
(2) Indicates lamp-ON.
Fig 8.
Initial ignition of cold cathode fluorescent lamp via frequency sweep and load
resonance
Advantage of the sweep rather than a fixed ignition frequency is that sensitivity for spread
in resonance frequency is much lower.
Once the lamps are ignited the frequency sweep-down continues, gradually increasing the
lamp current (the resonance circuit should now still be inductive, so current increases as
frequency drops) until the current regulation level is reached (at fsw = freg). The frequency
will not reach fsw(min) if the lamp current comes into regulation. Once it has been detected
that the lamps are on (if the average absolute voltage at the current feedback input (pin
IFB) is above Vth(lod)(IFB)) PWM dimming is enabled. See Figure 9.
The initial ignition frequency sweep and the PWM generator are not synchronized. Once
the regulation frequency is reached, PWM dimming can start anywhere in its cycle. A
small internal PWM dimming enable delay time, td(en)PWM, allows the lamps to settle
before PWM dimming starts.
At the start of the lamps-off period of the PWM dimming, the switching frequency is swept
up to fsw(max). This reduces the lamp voltage so the lamps go out. If fsw(max) is reached,
both GL and GH are made low, so both half bridge powers will be non-conducting. This is
indicated by the dotted part of the switching frequency (fsw) line in Figure 9.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
12 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
ignition
max
fsw
fign
freg
min
0
t
ov
Vsec
0
t
VCVFB
max
VCVFB
VCIFB
VCSWP
VCIFB
VCSWP
0
t
0
t
VPWMD
nom
Ilamp
0
initial
ignition
sweep
PWM-enable delay
t
steady-state
014aaa104
Fig 9.
Initial ignition frequency sweep and PWM dimming frequency sweep signals
The lamps start switching again on period GL and GH and the frequency is swept back to
the regulation frequency freg. The duration of the PWM frequency sweep is inverse
proportional to the capacitor connected to the CSWP pin.
8.9 Overvoltage control
The overvoltage control circuit is intended to prevent the transformer output voltage from
exceeding its maximum rating. It can also be used to regulate the output voltage to the
required lamp ignition voltage.
Under normal circumstances the capacitor at the CVFB pin is charged by a constant bias
current Ich(CVFB), thus the voltage on the CVFB pin will increase resulting in a decrease of
switching frequency. If the IC is in current regulation this bias current will flow away via a
tracking circuit which makes the voltage on the CVFB pin following the voltage on the
CIFB pin, see Figure 11.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
13 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
When the voltage on the VFB pin exceeds Vth(ov)(VFB), a fault condition is signalled (for
handling of fault conditions, see Section 8.14) and the bias current at the CVFB pin
changed to the discharge current Idch(CVFB). As a result, the switching frequency increases
and the output voltage of the transformer will decrease5. As soon as the voltage at the
VFB pin drops below Vth(ov)(VFB), the CVFB capacitor is charged again and the output
voltage of the transformer will increase again. Because the charging and discharging of
the CVFB capacitor follows the ripple on the VFB pin voltage, the feedback gain of the
voltage control loop is set by the ripple on the feedback signal.
The voltage at the CVFB pin is limited by the oscillator circuit to VCVFB(max) when the
minimum switching frequency fsw(min) is reached, see Figure 10. This ensures an
immediate frequency increase when overvoltage is detected.
fsw(max)
frequency
fsw(min)
0
VCVFB(max)
Voltage on CVFB-pin
014aaa105
Fig 10. Frequency function of CVFB voltage
8.10 Lamp current control
The lamp current control is always active when the IC is on, except if the lamps are off
during PWM dimming. The AC lamp current is sensed by an external resistor connected
to the IFB pin, see Figure 11. The resulting AC voltage on the IFB pin is internally
Double-Sided Rectified (DSR) and compared to a reference level Vref(creg) by an
Operational Transconductance Amplifier (OTA).
When the current is being regulated, switch S1 is closed (conducting). The output current
of the OTA is fed into capacitor C1, which is connected to the CIFB pin. So C1 is charged
and discharged according to the voltage on the IFB pin.
5.
Presuming that the load impedance is in inductive region.
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
14 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Ich(CSWP)
Idch(CSWP)
to CCFLs
OTA
0
IFB
PWMD
1
S2
DSR
S1
R1
Vref(creg)
to VCO
Ich(CVFB)
UBA2071
CIFB
CVFB
C1
C2
CSWP
C3
014aaa106
Fig 11. Lamp frequency control circuit
Under normal operating conditions, the voltage across capacitor C2, which is connected
to the CVFB pin, will follow the voltage on the CIFB pin. During the lamps-on period of the
PWM dimming, the voltage across C3, which is connected to the CSWP pin, will follow the
voltage on the CVFB pin and therefore also the voltage on the CIFB pin.
The voltage on the CSWP pin is connected to the VCO input of the HF oscillator and thus
controls the switching frequency. If the load is assumed to be inductive an increase in the
frequency will cause a decrease in the lamp current, while a decrease in the frequency will
cause an increase in the lamp current.
The advantage of having a separate current regulation loop timing capacitor pin CIFB next
to the voltage regulation loop timing capacitor CVFB is that time constants for both loops
can be set independently. The separate PWM dimming sweep timing capacitor pin CSWP
makes it possible to set the PWM dimming sweep speed independent of the current and
voltage regulation loops.
8.11 PWM dimming
Pulse Width Modulation (PWM) dimming is a method of reducing the average lamp light
output by switching the lamps on and off with a repetition rate or PWM frequency, fPWM,
high enough not to be seen by the human eye (but much lower than the inverter frequency
fsw). By varying the lamp-on to lamp-off, period ratio, called the duty cycle δPWM, the light
output can be varied over a wide range.
The voltage at the CSWP pin determines the actual switching frequency, it inverses in
proportion to the switching frequency. During the lamps-on period of the PWM dimming it
follows the voltage at the CVFB pin (the current Ich(CSWP) is drained by the tracking circuit
between the CVFB pin and the CSWP pin).
Just prior to transitioning towards the lamps-off period of the PWM dimming the lamp
current control loop, see Figure 11, is opened by opening switches S1. The voltage on the
CSWP pin is swept down, decaying the lamp current, leading in the PWM lamp-off
situation, after which the half bridge switch actions are stopped, resulting in true zero lamp
current. see Figure 9. In the meantime the regulation level is preserved in C1 and C2. The
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
15 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
PWM lamp-on situation is reached again through a reverse sequence of events, starting
the half bridge actions, increasing the voltage on CSWP, increasing the lamp current back
to the controlled value. Switch S1 is closed (conducting) again when the voltage on the
CSWP pin has reached the voltage on the CVFB pin again.
The IC waits until the CSWP sweep-up6 has reached the current/voltage control level at
the CVFB pin before sweeping down. This prevents the lamps from going out completely
when deep dimming on CSWP pin is combined with a large value capacitor.
After the switching frequency has reached fsw(max), both GL and GH are made low, so both
half bridge powers will be non-conducting, see Figure 12. This guarantees zero lamp
current during the PWM-off period7, while the CSWP frequency sweep acts as soft stop
and soft restart, of which the softness can be set by the value of the capacitor connected
to the CSWP pin.
max
reg
VCSWP
0
t
5V
VPWMD
0
t
VDD
VGH − VSH
0
t
VDD
VGL
0
t
014aaa107
Fig 12. PWM dim cycle waveforms
Three pins are available to configure the internal PWM generator: the CPWM pin, PWMA
pin, and the PWMD pin. The two possible PWM configurations are shown in Figure 13. In
the analog or master mode the internal PWM generator is active and generating the PWM
signal. This signal is put on the PWMD pin, which is automatically configured as an
output. The minimum duty cycle of the internal PWM generator is limited to δPWM(min).
6.
7.
CSWP sweep-up is frequency sweep-down.
Until the ringing of voltage on the half bridge point has died away, some (capacitive) current may still cause a light glow at the hot
side of the lamps. Therefore it is advised to maximize the attenuation of the ringing circuit (made up by the transformer inductance
and the ∆V/∆t limiting capacitor).
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
16 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
CPWM
CPWM
9
9
C1
analog in
PWMA 14
RPWMA
PWMA 14
VPWMA(ref)
PWM out
PWM in PWMD 13
PWMD 13
PWM intern
PWM intern
UBA2071
A: analog or master mode
UBA2071
B: digital or slave mode
014aaa108
Fig 13. PWM dimming configurations
When the CPWM pin is connected to ground the IC is put in digital or slave mode and the
PWMD pin is an input. The internal PWM generator is not used. The IC uses the PWM
signal provided on the PWMD pin.
PWM dimming of multiple ICs can be synchronized by configuring one IC as master and
the others as slaves and connecting all PWMD pins together.
The PWMD input/output is active low. A voltage below Vth(L)(PWMD) on the pin will turn the
lamps on, while a voltage above Vth(H)(PWMD) will turn the lamps off.
PWM dimming is only enabled in normal mode, when no fault condition exists. The only
exception is when an external detected fault condition is entered via the NONFAULT pin,
then PWM dimming remains active, see Figure 15.
8.12 The fault timer
The fault timer provides a delay in between the detection of a fault and the shutdown of
the IC (enter STOP state). Its time is controlled by a capacitor at the CT pin.
Any fault condition will start the timer. When the timer is activated, the capacitor at the
CT pin will be alternatively charged and discharged, see Figure 14. After the fault output
delay time, td(o)fault), the NONFAULT pin is activated (pulled low). This is to signal to any
external circuit that a fault has been detected and the IC will stop if that fault continues.
After the fault time-out period tto(fault) is reached the IC will enter STOP state.
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
17 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
VCT
0
t
VNONFAULT
0
t
td(o)fault
tto(fault)
IC in
STOP-state
014aaa110
Fig 14. Fault timer waveforms
If the fault timer is inactive, the CT pin voltage is 1 Vbe, about 0.7 V. The CT timer has a
protection that prevents the IC to start up if the CT pin is shorted to GND.
8.13 Communication
The UBA2071 and UBA2071A have a dedicated communication pin, the COMM pin, for
communicating with a slave half bridge driver (like the UBA2073), for instance for use in a
balanced half bridge driver configuration.
Via the COMM pin, a clock signal and a signal to indicate that both half bridge powers are
to be turned off are exported and a fault signal is imported. The clock signal is a digital
signal with a low level VL(clk)(COMM) and a high level VH(clk)(COMM). To signal that both half
bridge powers should be turned off, the voltage at the COMM pin is raised to
VO(hbswoff)(COMM).
The UBA2071 and UBA2071A look at the current drawn from the COMM pin during the
clock high period for a hard switching signal from the slave half bridge driver. First, a
non-overlap time period tno is discarded to prevent that a capacitive load on the
communication line is seen as a signal. Then the detected current is averaged over the
clock high period before being compared to the reference level Ith(det)hsw(COMM). The
current value is sampled on the falling edge of the clock signal and held during the clock
low period. The received signal is treated as equal to an internal hard switching detection
(so PWM dimming will be disabled, switching frequency will be increased and fault timer
will be started).
When only the UBA2071 or UBA2071A is used, the COMM pin must be “not connected”.
8.14 Protections
All fault conditions and how they are processed in the IC can be found in Figure 15.
The UBA2071 and UBA2071A have the following protections:
• OverVoltage Protection (OVP),
• OverVoltage Extra protection (OVE),
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
18 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
•
•
•
•
•
•
OverCurrent Protection (OCP),
bad contact or ARCing (ARC),
Ignition Failure (IF),
open or shorted current feedback (IFB pin open/short),
open or shorted voltage feedback (VFB pin open/short)
Hard Switching (HS).
There are also two pins, the NONFAULT pin and the COMM pin, via which a fault can be
signalled to the IC, by an external circuit.
enable
low_supply
NONFAULT-pin_fault_signal
IFB_open / short
over_voltage_extra
over_voltage
VFB_open / short
over_current
f_max
arcing_detected
COMM-pin_fault_signal
hard_switching_detected
ic_off
R
stop
lamp_on
Q
lamp_current_detected
FAULTTIMER
FILTER
S
ignition_
failure
f_min
R
Q
DELAY
S
enable_PWM_
dimming
014aaa111
Fig 15. Simplified control schematic
The fault protection functions are explained in the following sections.
8.14.1 Voltage feedback open or short protection
If the VFB pin is left open or shorted to SGND, the voltage at the VFB pin will drop below
the VFB open/short protection threshold voltage Vth(osp)VFB, due to the internal bias
resistor Ri(VFB). If the voltage at the VFB pin is below Vth(osp)VFB continuously or only
during a part of each switching cycle the PWM dimming is disabled and the fault timer is
started.
To protect the inverter transformer(s) against overvoltage if the voltage feedback loop is
broken, the frequency stays at fsw(max) or is increased by discharging the capacitor at the
CVFB pin (by Idch(CVFB)). For this function the voltage at the VFB pin has to be below
Vth(osp)VFB during more than 50 % of each switching cycle.
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
19 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
8.14.2 Overvoltage protection
The overvoltage control, see Section 8.9, is intended to prevent the transformer output
voltage from exceeding its maximum rating. The overvoltage control level has to be at
least at the required lamp ignition voltage, otherwise the lamps may not ignite.
Once the lamps are on and in steady state, the transformer output voltage will usually be
about half the required ignition voltage for CCFLs. Thermal design of the transformers is
based on this lower voltage, not on the ignition voltage above which the overvoltage
control has to be. Hence the circuit might not stay in overvoltage regulation indefinitely.
Therefore overvoltage regulation is combined with overvoltage protection.
When the voltage on the VFB pin exceeds the OV reference level Vth(ov)(VFB), the CVFB is
discharged, an overvoltage fault condition is signalled, PWM dimming is disabled, and the
fault timer is started. An internal latch makes the OV fault signal continuously high, even if
the voltage at the VFB pin only exceeds Vth(ov)(VFB) during part of the output period. So the
peak of the voltage on the VFB pin determines if an overvoltage fault condition is seen. An
internal filter prevents the overvoltage fault condition from being reset when the voltage at
the VFB pin drops below the OV reference level for only one or two hf cycles.
In order to avoid an OV fault condition at the nominal switching frequency (with the lamps
operating normally), the voltage ripple on the VFB pin must not be too large.
8.14.3 Hard switching protection
As the UBA2071 and UBA2071A are intended to drive a half bridge at a high voltage, a
feature is included to ensure zero voltage switching. The design of the resonant load
should guarantee zero voltage switching under normal operating conditions. To prevent
overheating due to high switching losses in case of any abnormal operating condition,
hard switching of the half bridge is detected internally.
At the moment the high-side switch is turned on, the voltage step at the SH pin is
measured. If it is above Vth(hsw)(SH) then PWM dimming is disabled and the fault timer is
started. Also, the frequency is increased by discharging the capacitor at the CVFB pin (by
Idch(CVFB)).
8.14.4 Overvoltage extra protection
Though the hard switching protection as described in Section 8.14.3, usually prevents the
circuit from getting at the wrong side of the resonance curve of the load (were the load
shows capacitive behavior), this might happen for instance when a lamp is suddenly
disconnected. The parasitic capacitance of the lamp and its connection wire may make up
a significant part of the resonance circuit capacitance, so if a lamp is disconnected the
resonance frequency of the remaining load is suddenly higher and the switching
frequency might be at the capacitive side. Hard switching will occur and be detected. The
result is an increase in the switching frequency, which will make the situation worse: the
switching frequency comes closer to the resonance frequency of the remaining load,
creating a higher and potentially destructive transformer secondary voltage.
The OverVoltage Extra (OVE), protection prevents damage to the circuit by adding an
extra overvoltage protection level with quick response to that. When the voltage on the
VFB pin exceeds this OVE level Vth(ovextra)(VFB), an OVE fault condition is signalled. The IC
will stop if this happens during a couple of subsequent hf cycles. The time it takes before
the IC stops depends on a percentage of the time the VFB pin voltage exceeds the OVE
level and if hard switching is detected also. Figure 16 shows typical shutdown response
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
20 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
times in case overvoltage and overvoltage extra are detected at the same moment (curve
(1)) and if overvoltage, overvoltage extra and hard switching are detected at the same
moment (curve (2)). The first parts of the curves are dashed because an internal filter
makes that VFB needs to be above Vth(ovextra)(VFB) for at least about 1 µs for the
overvoltage extra to react at all.
If a normal overvoltage fault was already present for more than about 840 µs before
overvoltage extra detection started or hard switching was already detected for more than
about 55 µs before overvoltage extra detection started, then the IC will shut down about
1 µs after overvoltage extra is detected.
014aaa112
500
stop time
(µs)
400
300
200
(1)
100
(2)
0
0
20
40
60
80
100
VFB above OVE (%)
Fig 16. Shutdown time at over voltage extra detection
8.14.5 Current feedback open or short protection
If the IFB pin is left open or shorted to SGND, the peak of the absolute value of the voltage
at the IFB pin will be below the IFB open/short protection threshold Vth(osp)(IFB) and the
fault timer is started.
The IFB open/short protection looks only at the IFB pin voltage if the voltage at the CSWP
pin is equal to the voltage at the CVFB pin. During PWM dimming this is when the lamps
are on and in current regulation or voltage regulation (so not during PWM lamps-off period
and not during the re-ignition frequency sweep).
8.14.6 Overcurrent detection
When the peak of the absolute value of the voltage across the current sense resistor
(connected to the IFB pin) exceeds the OC reference level Vth(ocd)(IFB) and the IC is
oscillating at fsw(max), overcurrent is detected. As result PWM dimming is disabled and the
fault timer is started.
8.14.7 Arcing detection
If arcing occurs, for instance due to a bad lamp connection, it causes repetitive short
current spikes that can be seen as voltage spikes at the IFB input. The arcing detection
circuit is directly connected to the IFB pin, so it can only see spikes with a positive polarity.
Usually that will be sufficient. It can detect spikes with amplitude above Vth(det)arc(IFB) and a
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
21 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
duration longer than tspike(min). Each spike will trigger an internal one-shot, which signals to
the control circuits that arcing has been detected. When arcing is detected, PWM dimming
is disabled and the fault timer is started.
8.14.8 Ignition Failure (IF)
When the current control loop comes close to its regulation point, the lamps are assumed
to be on (ignited). This is when the average absolute voltage on the IFB pin is above
Vth(lod)(IFB). If the lamps are not on when the ignition sweep is finished, (switching
frequency has reached fsw(min)), then an ignition failure is detected, PWM dimming is
disabled and the fault timer is started.
8.14.9 The NONFAULT pin
The NONFAULT pin provides bidirectional signalling of the fault status between the IC and
any external circuit. When no fault is detected, the voltage on the pin is pulled high to
Voc(NONFAULT) by an internal current source.
An external circuit can signal to the IC that a fault has been detected by pulling a current
larger than Itrig(I)NONFAULT from the NONFAULT pin. The IC will detect the current drawn
from the pin and start the fault timer. To prevent interference with the PWM dimming, the
IC will only look at the NONFAULT pin during the period when the lamp current regulation
loop is closed (when V CSWP = V CVFB ).
When the IC detects an internal fault, see Section 8.14.2 to Section 8.14.8), it signals this
via the NONFAULT pin by pulling the pin down (after the fault output delay time td(o)fault)).
At this point the IC can no longer detect the external fault. However, by then the fault timer
is already running.
NONFAULT
pin voltage
Voc(NONFAULT)
Vtrig(I)NONFAULT
load line
1V
in: low (active)
out: high (inactive)
Isc(NONFAULT)
0
in: high (inactive)
out: high (inactive)
in: unknown
out: low (active)
Itrig(I)NONFAULT
NONFAULT
pin current
Isink(NONFAULT)
014aaa113
Fig 17. Input and output levels at the NONFAULT pin
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
22 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
The signal from the IC is a voltage signal and the signal to the IC is a current signal. In this
way a driving conflict is prevented. Also, it leaves the possibility for the outside world to
see the signal from the IC even while a fault condition is being signalled to the IC in the
meantime, as illustrated in Figure 18.
UBA2071
to IC
NONFAULT
from IC
014aaa114
Fig 18. Splitting the NONFAULT pin signals to and from the IC
8.14.10 Fault input via the COMM pin
If a fault is signalled to the IC via the COMM pin this fault is treated identical to hard
switching detected, see Section 8.14.3.
9. Limiting values
Table 4.
Limiting values
In accordance with the Absolute Maximum Rating System (IEC 60134). All voltages are measured with respect to signal
ground (SGND pin 10).
Symbol
Parameter
Conditions
Min
Max
Unit
30
36
kΩ
General
Rref(IREF)
reference resistance on pin
IREF
SR
slew rate
−4
+4
V/ns
Tamb
ambient temperature
−25
+100
°C
Tj
junction temperature
−25
+125
°C
Tstg
storage temperature
−55
+150
°C
VSH
voltage on pin SH
-
550
V
VVDD
voltage on pin VDD
-
14
V
VFS
voltage on pin FS
0
+570
V
t < 0.5 s
0
+630
V
with respect to VSH
−0.3
+14
V
−0.3
+14
V
−0.3
+14
V
on pins FS, GH, and SH
Voltages
continuous
VGL
voltage on pin GL
VGH
voltage on pin GH
VPGND
voltage on pin PGND
0.0
0.0
V
VVDD
voltage on pin VDD
−0.3
+14
V
VCOMM
voltage on pin COMM
−0.3
+14
V
VEN
voltage on pin EN
−0.3
+14
V
VPWMA
voltage on pin PWMA
−0.1
+5
V
VPWMD
voltage on pin PWMD
−0.1
+5
V
with respect to VSH
UBA2071_A_1
Product data sheet
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Rev. 01 — 23 June 2008
23 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 4.
Limiting values …continued
In accordance with the Absolute Maximum Rating System (IEC 60134). All voltages are measured with respect to signal
ground (SGND pin 10).
Symbol
Parameter
VNONFAULT
voltage on pin NONFAULT
VVFB
voltage on pin VFB
voltage on pin IFB
VIFB
Conditions
Min
Max
Unit
−0.1
+5
V
continuous
−0.1
+5
V
t < 1 ms
−0.1
+9
V
continuous
−5
+5
V
t < 1 ms
−9
+9
V
pins IFB, CIFB, VFB, CVFB,
CSWP, IREF, CT, CF, CPWM,
NONFAULT, COMM, PWMA,
PWMD, EN, VDD, and GL
−2
+2
kV
pins GH, FS, and SH
−1
+1
kV
−250
+250
V
ESD
electrostatic discharge voltage
VESD
human body model:
machine model:
all pins
10. Thermal characteristics
Table 5.
Thermal characteristics
Symbol
Parameter
Conditions
Typ
Unit
Rth(j-a)
thermal resistance from
junction to ambient
in free air; SO24 package
80
K/W
in free air; SSOP24 package
111
K/W
11. Characteristics
Table 6.
Characteristics
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless otherwise specified. All
voltages are measured with respect to signal ground (SGND, pin 10). SGND and PGND connected together. GL, GH,
COMM, NONFAULT and PWMD pins left open (unless otherwise specified). Currents are positive when flowing into the IC.
Parameters valid for all types (unless otherwise specified).
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
leakage current
VFS, VGH, and VSH = 630 V;
VVDD = 0 V
-
-
2
µA
Vstartup(VDD)
VDD start-up voltage
UBA2071T and UBA2071TS
11.7
12.1
12.5
V
Vstop(VDD)
stop voltage on pin VDD
Vhys(VDD)
hysteresis voltage on pin VDD
High voltage
Ileak
Start-up
UBA2071AT and UBA2071ATS
Istartup(VDD)
start-up current on pin VDD
10.5
10.9
11.3
V
9.8
10.1
10.4
V
UBA2071T and UBA2071TS
1.8
2
2.2
V
UBA2071AT and UBA2071ATS
0.6
0.8
1.0
V
VVDD = 11 V; EN pin grounded
0.13
0.16
0.19
mA
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
24 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 6.
Characteristics …continued
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless otherwise specified. All
voltages are measured with respect to signal ground (SGND, pin 10). SGND and PGND connected together. GL, GH,
COMM, NONFAULT and PWMD pins left open (unless otherwise specified). Currents are positive when flowing into the IC.
Parameters valid for all types (unless otherwise specified).
Symbol
Parameter
Conditions
Min
Typ
Vclamp(VDD)
clamp voltage on pin VDD
EN pin grounded; IVDD = 0.22 mA;
UBA2071T and UBA2071TS
13
13.35 13.7
V
EN pin grounded; IVDD = 3 mA;
UBA2071T and UBA2071TS
-
-
14.0
V
EN pin grounded; VVDD = 14.0 V;
UBA2071AT and UBA2071ATS
-
-
0.22
mA
IVDD
current on pin VDD
Max
Unit
Ignition
fsw(max)/fsw(min)
maximum switching frequency
to minimum switching
frequency ratio
2.2
2.4
2.6
kHz
VCVFB(max)
maximum voltage on pin CVFB
-
2.5
-
V
Ich(CVFB)
charge current on pin CVFB
Vth(lod)(IFB)
lamp on detection threshold
voltage on pin IFB
−24
−21
−18
µA
0.9
1.05
1.2
V
oscillating at fsw(min);
CCF = 100 pF
1.2
1.5
1.8
mA
disabled; VVDD = 11 V
-
0.16
-
mA
oscillating; CF = 100 pF;
GL and GH open
-
1.5
-
mA
[1][2]
10
-
100
kHz
[1][2]
38
40
42
kHz
1.20
1.26
1.32
V
VVFB = 2 V; VCVFB(max) = 2 V
Normal operation
IVDD
fsw(min)
current on pin VDD
minimum switching frequency
CCF = 100 pF
Vref(creg)
current regulation reference
voltage
VIFB(min)
minimum voltage on pin IFB
for linear operating range
-
−2.5
-
V
VIFB(max)
maximum voltage on pin IFB
for linear operating range
-
2.5
-
V
Ri(IFB)
input resistance on pin IFB
VIFB = 1 V
-
45
-
kΩ
VIFB = −1 V
-
24
-
kΩ
gm(OTA)
OTA transconductance
14
16.5
19
µA/V
Drivers
Isource(drv)
driver source current
VGL, VGH = 4 V;
VVDD = VFS = 12 V
−105
−90
−75
mA
Rsink(drv)
driver sink resistance
VGL, VGH = 2 V;
VVDD = VFS = 12 V
13.5
16.0
18.5
Ω
tno
non-overlap time
1.1
1.3
1.5
µs
VFd(bs)
bootstrap diode forward
voltage
IFS = 5 mA
1.0
1.5
2.0
V
IVDD
current on pin VDD
CCF = 100 pF; VPWMD = H;
VCSWP = 0 V
1.0
1.2
1.4
mA
td(en)PWM
PWM enable delay time
3
4
5
ms
PWM dimming
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
25 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 6.
Characteristics …continued
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless otherwise specified. All
voltages are measured with respect to signal ground (SGND, pin 10). SGND and PGND connected together. GL, GH,
COMM, NONFAULT and PWMD pins left open (unless otherwise specified). Currents are positive when flowing into the IC.
Parameters valid for all types (unless otherwise specified).
Symbol
Parameter
fPWM
PWM frequency
Conditions
Min
Typ
Max
Unit
75
-
1000
Hz
CCPWM = 33 nF
306
324
342
Hz
[1]
Ich(CSWP)
charge current on pin CSWP
PWMD low; VCSWP = 1 V
−23
−20
−17
µA
Idch(CSWP)
discharge current on pin
CSWP
PWMD high; VCSWP = 1 V
17
20
23
µA
Ri(PWMA)
input resistance on pin PWMA
80
100
120
kΩ
Vi(PWMA)
input voltage on pin PWMA
-
1.24
-
V
δPWM(min)
minimum PWM duty cycle
for minimum PWM duty cycle
for maximum PWM duty cycle
-
3
-
V
[3]
-
12
-
%
[3]
-
0
-
%
maximum PWM duty cycle
[3]
-
100
-
%
δPWMD
duty cycle on pin PWMD
[3]
12
-
100
%
Isource(PWMD)
source current on pin PWMD
VPWMD = 3 V
-
0.6
-
mA
Isink(PWMD)
sink current on pin PWMD
VPWMD = 1 V
-
1.2
-
mA
Vth(H)(PWMD)
HIGH-level threshold voltage
on pin PWMD
-
-
1.7
V
Vth(L)(PWMD)
LOW-level threshold voltage on
pin PWMD
0.85
-
-
V
CPWM pin connected to SGND
δPWM(max)
Communication (COMM pin)
VL(clk)(COMM)
clock LOW-level voltage on pin ICOMM = 10 µA
COMM
0
0.1
0.2
V
IL(clk)(COMM)
clock LOW-level current on pin
COMM
-
5.0
-
mA
VH(clk)(COMM)
clock HIGH-level voltage on pin ICOMM = −10 µA
COMM
4
4.3
4.6
V
IH(clk)(COMM)
clock HIGH-level current on pin VCOMM = 2.5 V
COMM
-
−4.5
-
mA
VO(hbswoff)(COMM)
half bridge switch-off output
voltage on pin COMM
PWMD = 5 V
-
12
-
V
Ith(det)hsw(COMM)
hard switching detection
threshold current on pin
COMM
Clock = high; PWMD = low
−120
−100
−80
µA
VCOMM = 1.5 V
Protections
Vth(osp)(VFB)
open/short protection threshold
voltage on pin VFB
50
100
150
mV
Vth(ov)(VFB)
overvoltage threshold voltage
on pin VFB
2.40
2.50
2.60
V
Ri(VFB)
input resistance on pin VFB
500
670
840
kΩ
Idch(CVFB)
discharge current on pin CVFB VVFB < Vth(osp)(VFB) or
VVFB > Vth(ov)(VFB); VCVFB = 2 V
17
20
23
µA
Vth(ovextra)(VFB)
overvoltage extra threshold
voltage on pin VFB
2.9
3.0
3.1
V
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
26 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
Table 6.
Characteristics …continued
Tamb = 25 °C; VVDD = 12 V; RIREF = 33 kΩ; VEN = VVDD and CPWM connected to a capacitor, unless otherwise specified. All
voltages are measured with respect to signal ground (SGND, pin 10). SGND and PGND connected together. GL, GH,
COMM, NONFAULT and PWMD pins left open (unless otherwise specified). Currents are positive when flowing into the IC.
Parameters valid for all types (unless otherwise specified).
Symbol
Parameter
Min
Typ
Max
Unit
Vth(osp)(IFB)
open/short protection threshold
voltage on pin IFB
Conditions
200
250
300
mV
Vth(ocd)(IFB)
overcurrent detection threshold
voltage on pin IFB
2.65
3.0
3.3
V
Vth(hsw)(SH)
hard switching threshold
voltage on pin SH
-
56
-
V
Idch(CVFB)
discharge current on pin CVFB hard switching detected;
VCVFB = 2 V
36
41
46
µA
Vth(det)arc(IFB)
arc detection threshold voltage
on pin IFB
-
5
-
V
tspike(min)
minimum spike time
to active arcing protection
-
200
-
ns
td(o)fault
fault output delay time
CCT = 100 nF
0.063 0.069 0.075 s
tto(fault)
fault time-out time
CCT = 100 nF
0.85
1.00
1.15
s
Voc(NONFAULT)
open-circuit voltage on pin
NONFAULT
4.7
5.0
5.3
V
Vtrig(I)NONFAULT
input trigger voltage on pin
NONFAULT
3.8
4.3
4.8
V
Itrig(I)NONFAULT
input trigger current on pin
NONFAULT
−32
−27
−22
µA
INONFAULT
current on pin NONFAULT
VNONFAULT = 3 V
−230
−195
−160
µA
Isc(NONFAULT)
short circuit current on pin
NONFAULT
VNONFAULT = 0 V
−260
−220
−180
µA
Isink(NONFAULT)
sink current on pin NONFAULT VNONFAULT = 1 V
0.7
1
1.3
mA
Vth(H)2(EN)
HIGH-level threshold voltage 2
on pin EN
2.65
2.76
2.87
V
Vth(H)1(EN)
HIGH-level threshold voltage 1
on pin EN
-
-
1.7
V
Vth(L)(EN)
LOW-level threshold voltage on
pin EN
0.9
-
V
Ibias(EN)
bias current on pin EN
5
µA
Enable (EN pin)
[1]
Given frequency is switching frequency of GL and GH. Sawtooth frequency on CF pin is twice as high.
[2]
Can be set by external capacitor
[3]
PWMD is active low: A low level on the PWMD pin corresponds with lamps-on. Example: δPWM = 20 % means PWMD is low during 20 %
of each cycle and the lamps are on 20 % of the time, resulting in a light output of 20 %.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
27 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
12. Application information
Figure 19 shows an example backlighting configuration, where the inverter is supplied
from a high voltage DC source and the IC is supplied by means of a ∆V/∆t supply (C14,
C15, Z1 and D1). Two lamps are connected, each to the output of its own transformer. The
leakage inductance of this transformer provides the ballast impedance for the lamps. An
analog voltage is converted to a PWM signal to provide for the desired brightness level.
Lamp short detection is done via the lamp voltage sensing, D13 and D23, and the
NONFAULT pin.
Figure 20 shows an example of a balanced application using one UBA2071 and one
UBA2073.
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
28 of 35
xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx
xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x
xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx
xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx
R4
(1)
HVDC
D1
NONFAULT
GND
CN1
NXP Semiconductors
UBA2071_A_1
Product data sheet
C1
R2
C15
C2
VDD
EN
NONFAULT
GH
EN
FS
PWMA
C3
PWMD
C4 CVFB
Z1
CCFL 1
C10
C9
CIFB
C5
CT
C6
CF
D13
C11
SH
D11
D14
C12
D12
R11
C13
UBA2071
C7 CSWP
R1
Q1
C14
GL
Q2
T1
IREF
CCFL 2
D23
C21
C8 CPWM
D21
D24
PWMA
C22
PWMD
D22
R21
C23
PGND
IFB
R3
R5
R6
014aaa115
29 of 35
© NXP B.V. 2008. All rights reserved.
(1) Optional lamp short protection is available via the NONFAULT pin.
Fig 19. Example of single IC backlighting application
UBA2071; UBA2071A
VFB
COMM
Half bridge control IC for CCFL backlighting
Rev. 01 — 23 June 2008
SGND
xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx
xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x
xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx
xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx
NXP Semiconductors
UBA2071_A_1
Product data sheet
HVsupply
UBA2071
UBA2073
VDD
GH
GH
IREF
SH
SH
CF
FS
FS
GL
GL
VDD
CT
CSWP
CVFB
CIFB
CPWM
PGND
SGND
IFB
PWMA
enable
EN
PWMD
PWMD
COMM
VFB
COMM
NONFAULT
Fig 20. Example of balanced backlighting application
30 of 35
© NXP B.V. 2008. All rights reserved.
UBA2071; UBA2071A
014aaa116
Half bridge control IC for CCFL backlighting
Rev. 01 — 23 June 2008
PWMA
PGND
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
13. Package outline
SO24: plastic small outline package; 24 leads; body width 7.5 mm
SOT137-1
D
E
A
X
c
HE
y
v M A
Z
24
13
Q
A2
A
(A 3)
A1
pin 1 index
θ
Lp
L
1
12
e
detail X
w M
bp
0
5
10 mm
scale
DIMENSIONS (inch dimensions are derived from the original mm dimensions)
UNIT
A
max.
A1
A2
A3
bp
c
D (1)
E (1)
e
HE
L
Lp
Q
v
w
y
mm
2.65
0.3
0.1
2.45
2.25
0.25
0.49
0.36
0.32
0.23
15.6
15.2
7.6
7.4
1.27
10.65
10.00
1.4
1.1
0.4
1.1
1.0
0.25
0.25
0.1
0.01
0.019 0.013
0.014 0.009
0.61
0.60
0.30
0.29
0.05
0.419
0.043
0.055
0.394
0.016
inches
0.1
0.012 0.096
0.004 0.089
0.043
0.039
0.01
0.01
Z
(1)
0.9
0.4
0.035
0.004
0.016
θ
o
8
o
0
Note
1. Plastic or metal protrusions of 0.15 mm (0.006 inch) maximum per side are not included.
REFERENCES
OUTLINE
VERSION
IEC
JEDEC
SOT137-1
075E05
MS-013
JEITA
EUROPEAN
PROJECTION
ISSUE DATE
99-12-27
03-02-19
Fig 21. Package outline SOT137-1 (SO24)
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
31 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
SSOP24: plastic shrink small outline package; 24 leads; body width 5.3 mm
D
SOT340-1
E
A
X
c
HE
y
v M A
Z
24
13
Q
A2
A
(A 3)
A1
pin 1 index
θ
Lp
L
1
12
w M
bp
e
detail X
0
2.5
5 mm
scale
DIMENSIONS (mm are the original dimensions)
UNIT
A
max.
A1
A2
A3
bp
c
D (1)
E (1)
e
HE
L
Lp
Q
v
w
y
Z (1)
θ
mm
2
0.21
0.05
1.80
1.65
0.25
0.38
0.25
0.20
0.09
8.4
8.0
5.4
5.2
0.65
7.9
7.6
1.25
1.03
0.63
0.9
0.7
0.2
0.13
0.1
0.8
0.4
8
o
0
o
Note
1. Plastic or metal protrusions of 0.2 mm maximum per side are not included.
OUTLINE
VERSION
SOT340-1
REFERENCES
IEC
JEDEC
JEITA
EUROPEAN
PROJECTION
ISSUE DATE
99-12-27
03-02-19
MO-150
Fig 22. Package outline SOT340 (SSOP24)
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
32 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
14. Revision history
Table 7.
Revision history
Document ID
Release date
Data sheet status
Change notice
Order number
Supersedes
UBA2071_A_1
20080623
Product data sheet
-
-
-
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
33 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
15. Legal information
15.1 Data sheet status
Document status[1][2]
Product status[3]
Definition
Objective [short] data sheet
Development
This document contains data from the objective specification for product development.
Preliminary [short] data sheet
Qualification
This document contains data from the preliminary specification.
Product [short] data sheet
Production
This document contains the product specification.
[1]
Please consult the most recently issued document before initiating or completing a design.
[2]
The term ‘short data sheet’ is explained in section “Definitions”.
[3]
The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple devices. The latest product status
information is available on the Internet at URL http://www.nxp.com.
15.2 Definitions
Draft — The document is a draft version only. The content is still under
internal review and subject to formal approval, which may result in
modifications or additions. NXP Semiconductors does not give any
representations or warranties as to the accuracy or completeness of
information included herein and shall have no liability for the consequences of
use of such information.
Short data sheet — A short data sheet is an extract from a full data sheet
with the same product type number(s) and title. A short data sheet is intended
for quick reference only and should not be relied upon to contain detailed and
full information. For detailed and full information see the relevant full data
sheet, which is available on request via the local NXP Semiconductors sales
office. In case of any inconsistency or conflict with the short data sheet, the
full data sheet shall prevail.
15.3 Disclaimers
General — Information in this document is believed to be accurate and
reliable. However, NXP Semiconductors does not give any representations or
warranties, expressed or implied, as to the accuracy or completeness of such
information and shall have no liability for the consequences of use of such
information.
Right to make changes — NXP Semiconductors reserves the right to make
changes to information published in this document, including without
limitation specifications and product descriptions, at any time and without
notice. This document supersedes and replaces all information supplied prior
to the publication hereof.
Suitability for use — NXP Semiconductors products are not designed,
authorized or warranted to be suitable for use in medical, military, aircraft,
space or life support equipment, nor in applications where failure or
malfunction of an NXP Semiconductors product can reasonably be expected
to result in personal injury, death or severe property or environmental
damage. NXP Semiconductors accepts no liability for inclusion and/or use of
NXP Semiconductors products in such equipment or applications and
therefore such inclusion and/or use is at the customer’s own risk.
Applications — Applications that are described herein for any of these
products are for illustrative purposes only. NXP Semiconductors makes no
representation or warranty that such applications will be suitable for the
specified use without further testing or modification.
Quick reference data — The Quick reference data is an extract of the
product data given in the Limiting values and Characteristics sections of this
document, and as such is not complete, exhaustive or legally binding.
Limiting values — Stress above one or more limiting values (as defined in
the Absolute Maximum Ratings System of IEC 60134) may cause permanent
damage to the device. Limiting values are stress ratings only and operation of
the device at these or any other conditions above those given in the
Characteristics sections of this document is not implied. Exposure to limiting
values for extended periods may affect device reliability.
Terms and conditions of sale — NXP Semiconductors products are sold
subject to the general terms and conditions of commercial sale, as published
at http://www.nxp.com/profile/terms, including those pertaining to warranty,
intellectual property rights infringement and limitation of liability, unless
explicitly otherwise agreed to in writing by NXP Semiconductors. In case of
any inconsistency or conflict between information in this document and such
terms and conditions, the latter will prevail.
No offer to sell or license — Nothing in this document may be interpreted
or construed as an offer to sell products that is open for acceptance or the
grant, conveyance or implication of any license under any copyrights, patents
or other industrial or intellectual property rights.
15.4 Trademarks
Notice: All referenced brands, product names, service names and trademarks
are the property of their respective owners.
16. Contact information
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: [email protected]
UBA2071_A_1
Product data sheet
© NXP B.V. 2008. All rights reserved.
Rev. 01 — 23 June 2008
34 of 35
UBA2071; UBA2071A
NXP Semiconductors
Half bridge control IC for CCFL backlighting
17. Contents
1
2
3
4
5
6
7
7.1
7.2
8
8.1
8.2
8.3
8.4
8.5
8.6
8.7
8.8
8.9
8.10
8.11
8.12
8.13
8.14
8.14.1
8.14.2
8.14.3
8.14.4
8.14.5
8.14.6
8.14.7
8.14.8
8.14.9
8.14.10
9
10
11
12
13
14
15
15.1
15.2
15.3
General description . . . . . . . . . . . . . . . . . . . . . . 1
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Quick reference data . . . . . . . . . . . . . . . . . . . . . 2
Ordering information . . . . . . . . . . . . . . . . . . . . . 3
Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Pinning information . . . . . . . . . . . . . . . . . . . . . . 5
Pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Pin description . . . . . . . . . . . . . . . . . . . . . . . . . 5
Functional description . . . . . . . . . . . . . . . . . . . 6
Supply, Start-up and UnderVoltage LockOut
(UVLO) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
VDD clamp. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Enable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
The oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Non-overlap . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Low-side and high-side drivers . . . . . . . . . . . . . 9
DC blocking capacitor charging . . . . . . . . . . . . 9
Lamp (re-)ignition . . . . . . . . . . . . . . . . . . . . . . 11
Overvoltage control. . . . . . . . . . . . . . . . . . . . . 13
Lamp current control. . . . . . . . . . . . . . . . . . . . 14
PWM dimming . . . . . . . . . . . . . . . . . . . . . . . . 15
The fault timer. . . . . . . . . . . . . . . . . . . . . . . . . 17
Communication. . . . . . . . . . . . . . . . . . . . . . . . 18
Protections . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Voltage feedback open or short protection . . . 19
Overvoltage protection . . . . . . . . . . . . . . . . . . 20
Hard switching protection . . . . . . . . . . . . . . . . 20
Overvoltage extra protection. . . . . . . . . . . . . . 20
Current feedback open or short protection . . . 21
Overcurrent detection . . . . . . . . . . . . . . . . . . . 21
Arcing detection . . . . . . . . . . . . . . . . . . . . . . . 21
Ignition Failure (IF) . . . . . . . . . . . . . . . . . . . . . 22
The NONFAULT pin . . . . . . . . . . . . . . . . . . . . 22
Fault input via the COMM pin . . . . . . . . . . . . . 23
Limiting values. . . . . . . . . . . . . . . . . . . . . . . . . 23
Thermal characteristics. . . . . . . . . . . . . . . . . . 24
Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 24
Application information. . . . . . . . . . . . . . . . . . 28
Package outline . . . . . . . . . . . . . . . . . . . . . . . . 31
Revision history . . . . . . . . . . . . . . . . . . . . . . . . 33
Legal information. . . . . . . . . . . . . . . . . . . . . . . 34
Data sheet status . . . . . . . . . . . . . . . . . . . . . . 34
Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
15.4
16
17
Trademarks . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Contact information . . . . . . . . . . . . . . . . . . . . 34
Contents. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Please be aware that important notices concerning this document and the product(s)
described herein, have been included in section ‘Legal information’.
© NXP B.V. 2008.
All rights reserved.
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: [email protected]
Date of release: 23 June 2008
Document identifier: UBA2071_A_1