PHILIPS TDA4854

INTEGRATED CIRCUITS
DATA SHEET
TDA4853; TDA4854
I2C-bus autosync deflection
controllers for PC/TV monitors
Product specification
Supersedes data of 1998 May 12
File under Integrated Circuits, IC02
1999 Jul 13
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
FEATURES
Concept features
• Full horizontal plus vertical autosync capability; TV and
VCR mode included
• Extended horizontal frequency range from
15 to 130 kHz
Vertical section
• Comprehensive set of I2C-bus driven geometry
adjustments and functions, including standby mode
• I2C-bus controllable vertical picture size, picture
position, linearity (S-correction) and linearity balance
• Very good vertical linearity
• Output for I2C-bus controllable vertical sawtooth and
parabola (for pin unbalance and parallelogram)
• Moire cancellation
• Start-up and switch-off sequence for safe operation of
all power components
• Vertical picture size independent of frequency
• Differential current outputs for DC coupling to vertical
booster
• X-ray protection
• Flexible switched mode B+ supply function block for
feedback and feed forward converter
• 50 to 160 Hz vertical autosync range.
• Internally stabilized voltage reference
East-West (EW) section
• Drive signal for focus amplifiers with combined
horizontal and vertical parabola waveforms (TDA4854)
• I2C-bus controllable output for horizontal pincushion,
horizontal size, corner and trapezium correction
• DC controllable inputs for Extremely High Tension
(EHT) compensation
• Optional tracking of EW drive waveform with line
frequency selectable by I2C-bus.
• SDIP32 package.
Focus section of TDA4854
Synchronization
• I2C-bus controllable output for horizontal and vertical
parabolas
• Can handle all sync signals (horizontal, vertical,
composite and sync-on-video)
• Vertical parabola is independent of frequency and tracks
with vertical adjustments
• Output for video clamping (leading/trailing edge
selectable by I2C-bus), vertical blanking and protection
blanking
• Horizontal parabola independent of frequency
• Pre-correction of delay in focus output stage.
• Output for fast unlock status of horizontal
synchronization and blanking on grid 1 of picture tube.
Horizontal section
• I2C-bus controllable wide range linear picture position,
pin unbalance and parallelogram correction via
horizontal phase
• Frequency-locked loop for smooth catching of horizontal
frequency
• TV mode at 15.625 or 15.750 kHz selectable by I2C-bus
• Simple frequency preset of fmin and fmax by external
resistors
• Low jitter
• Soft start for horizontal and B+ control drive signals.
1999 Jul 13
2
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
GENERAL DESCRIPTION
TDA4853; TDA4854
The TDA4854 provides extended functions e.g. as a
flexible B+ control, an extensive set of geometry control
facilities, and a combined output for horizontal and vertical
focus signals.
The TDA4854 is a high performance and efficient solution
for autosync monitors. All functions are controllable by
I2C-bus.
The TDA4853 is an economy version of the TDA4854,
especially designed for use in 14” and 15” monitors with
combined EHT generation. It provides the same features
as the TDA4854 except for the dynamic focus block.
The TDA4854 provides synchronization processing,
horizontal and vertical synchronization with full autosync
capability, a TV/VCR mode and very short settling times
after mode changes. External power components are
given a great deal of protection. The IC generates the drive
waveforms for DC-coupled vertical boosters such as the
TDA486x and TDA835x.
Together with the I2C-bus driven Philips TDA488x video
processor family, a very advanced system solution is
offered.
QUICK REFERENCE DATA
SYMBOL
PARAMETER
MIN.
TYP.
MAX.
UNIT
V CC
supply voltage
9.2
−
16
V
ICC
supply current
−
70
−
mA
ICC(stb)
supply current during standby mode
−
9
−
mA
VSIZE
vertical size
60
−
100
%
VGA
VGA overscan for vertical size
−
16.8
−
%
VPOS
vertical position
−
±11.5
−
%
VLIN
vertical linearity (S-correction)
−2
−
−46
%
VLINBAL
vertical linearity balance
−
±2.5
−
%
VHSIZE
horizontal size voltage
0.13
−
3.6
V
VHPIN
horizontal pincushion voltage (EW parabola)
0.04
−
1.42
V
VHEHT
horizontal size modulation voltage
0.02
−
0.69
V
VHTRAP
horizontal trapezium correction voltage
−
±0.33
−
V
VHCOR
horizontal corner correction voltage
−0.64
−
+0.08
V
HPOS
horizontal position
−
±13
−
%
HPARAL
horizontal parallelogram
−
±1
−
%
HPINBAL
EW pin unbalance
−
±1
−
%
Tamb
operating ambient temperature
−20
−
+70
°C
ORDERING INFORMATION
TYPE
NUMBER
PACKAGE
NAME
DESCRIPTION
VERSION
TDA4853
SDIP32
plastic shrink dual in-line package; 32 leads (400 mil)
SOT232-1
TDA4854
SDIP32
plastic shrink dual in-line package; 32 leads (400 mil)
SOT232-1
1999 Jul 13
3
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14
clamping
blanking
CLBL
16
VERTICAL
SYNC INPUT
AND POLARITY
CORRECTION
150
nF
1.2 V
VREF
VCAP
VAGC
VSMOD
HSMOD
EWDRV
23
24
22
21
31
11
EHT COMPENSATION
VERTICAL
OSCILLATOR
AND AGC
VERTICAL
SYNC
INTEGRATOR
VIDEO CLAMPING
AND
VERTICAL BLANK
7V
EHT compensation
via horizontal size
HORIZONTAL SIZE
AND
VERTICAL SIZE
EW-OUTPUT
17
VOUT2
VERTICAL LINEARITY
VERTICAL LINEARITY
BALANCE
13
VOUT1
VERTICAL POSITION
VERTICAL SIZE, VOVSCN
OUTPUT
ASYMMETRIC
EW-CORRECTION
HUNLOCK
12
VERTICAL OUTPUT
HORIZONTAL PINCUSHION
HORIZONTAL CORNER
HORIZONTAL TRAPEZIUM
HORIZONTAL SIZE
HUNLOCK
OUTPUT
20 ASCOR
or
PROTECTION
AND SOFT START
TDA4853
19
SDA
4
18
SCL
I2C-BUS
RECEIVER
X-RAY
I2C-BUS REGISTERS
6 BDRV
VCC
10
9.2 to 16 V
PGND 7
SGND 25
HSYNC
(TTL level)
15
4 BSENS
SUPPLY
AND
REFERENCE
COINCIDENCE DETECTOR
FREQUENCY DETECTOR
TV MODE
H/C SYNC INPUT
AND POLARITY
CORRECTION
PLL1 AND
HORIZONTAL
POSITION
3.3 kΩ
100 nF
X-RAY
PROTECTION
HORIZONTAL
OSCILLATOR
27
28
29
30
HPLL1
HBUF
HREF
HCAP
HPLL2
8.2
nF
RHBUF
(1)
10 nF
(2%)
8.2 nF
(2)
B+ CONTROL
APPLICATION
5 BIN
HORIZONTAL
OUTPUT
STAGE
PLL2, PARALLELOGRAM,
PIN UNBALANCE AND
SOFT START
26
3 BOP
1
9
2
HFLB
XSEL
XRAY
8 HDRV
32
MGM101
RHREF
(1%)
Fig.1 Block diagram and application circuit of TDA4853.
Product specification
(1) For the calculation of fH range see Section “Calculation of line frequency range”.
(2) See Figs 23 and 24.
i.c.
TDA4853; TDA4854
(video)
B+
CONTROL
Philips Semiconductors
VSYNC
(TTL level)
100
nF
(5%)
I2C-bus autosync deflection controllers for
PC/TV monitors
22
kΩ
(1%)
BLOCK DIAGRAMS
ook, full pagewidth
1999 Jul 13
EHT compensation
via vertical size
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VSYNC
14
(TTL level)
clamping
blanking
CLBL
16
17
HUNLOCK
VERTICAL
SYNC INPUT
AND POLARITY
CORRECTION
100
nF
(5%)
150
nF
1.2 V
VREF
VCAP
VAGC
VSMOD
HSMOD
EWDRV
23
24
22
21
31
11
EHT COMPENSATION
VERTICAL
OSCILLATOR
AND AGC
VERTICAL
SYNC
INTEGRATOR
VIDEO CLAMPING
AND
VERTICAL BLANK
7V
EHT compensation
via horizontal size
HORIZONTAL SIZE
AND
VERTICAL SIZE
EW-OUTPUT
SDA
5
18
SCL
VOUT2
VERTICAL LINEARITY
VERTICAL LINEARITY
BALANCE
13
VOUT1
VERTICAL POSITION
VERTICAL SIZE, VOVSCN
HUNLOCK
OUTPUT
OUTPUT
ASYMMETRIC
EW-CORRECTION
20 ASCOR
FOCUS
HORIZONTAL
AND VERTICAL
32 FOCUS
or
PROTECTION
AND SOFT START
TDA4854
19
12
VERTICAL OUTPUT
HORIZONTAL PINCUSHION
HORIZONTAL CORNER
HORIZONTAL TRAPEZIUM
HORIZONTAL SIZE
I2C-BUS
RECEIVER
X-RAY
I2C-BUS REGISTERS
6 BDRV
VCC
10
9.2 to 16 V
PGND
7
SGND
25
HSYNC
15
(TTL level)
4 BSENS
SUPPLY
AND
REFERENCE
COINCIDENCE DETECTOR
FREQUENCY DETECTOR
TV MODE
H/C SYNC INPUT
AND POLARITY
CORRECTION
PLL1 AND
HORIZONTAL
POSITION
3.3 kΩ
100 nF
X-RAY
PROTECTION
HORIZONTAL
OSCILLATOR
27
28
29
30
HPLL1
HBUF
HREF
HCAP
HPLL2
8.2
nF
RHBUF
(1)
10 nF
(2%)
8.2 nF
(2)
B+ CONTROL
APPLICATION
5 BIN
HORIZONTAL
OUTPUT
STAGE
PLL2, PARALLELOGRAM,
PIN UNBALANCE AND
SOFT START
26
3 BOP
1
9
2
HFLB
XSEL
XRAY
8 HDRV
MGM065
RHREF
(1%)
Fig.2 Block diagram and application circuit of TDA4854.
Product specification
(1) For the calculation of fH range see Section “Calculation of line frequency range”.
(2) See Figs 23 and 24.
TDA4853; TDA4854
(video)
B+
CONTROL
Philips Semiconductors
22
kΩ
(1%)
I2C-bus autosync deflection controllers for
PC/TV monitors
ook, full pagewidth
1999 Jul 13
EHT compensation
via vertical size
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
PINNING
SYMBOL
PIN
DESCRIPTION
HFLB
1
horizontal flyback input
XRAY
2
X-ray protection input
BOP
3
B+ control OTA output
BSENS
4
B+ control comparator input
BIN
5
B+ control OTA input
BDRV
6
B+ control driver output
PGND
7
power ground
HDRV
8
horizontal driver output
XSEL
9
select input for X-ray reset
VCC
10
supply voltage
EWDRV
11
EW waveform output
VOUT2
12
vertical output 2 (ascending sawtooth)
VOUT1
13
vertical output 1 (descending sawtooth)
VSYNC
14
vertical synchronization input
HSYNC
15
horizontal/composite synchronization input
CLBL
16
video clamping pulse/vertical blanking output
HUNLOCK
17
horizontal synchronization unlock/protection/vertical blanking output
SCL
18
I2C-bus clock input
SDA
19
I2C-bus data input/output
ASCOR
20
output for asymmetric EW corrections
VSMOD
21
input for EHT compensation (via vertical size)
VAGC
22
external capacitor for vertical amplitude control
VREF
23
external resistor for vertical oscillator
VCAP
24
external capacitor for vertical oscillator
SGND
25
signal ground
HPLL1
26
external filter for PLL1
HBUF
27
buffered f/v voltage output
HREF
28
reference current for horizontal oscillator
HCAP
29
external capacitor for horizontal oscillator
HPLL2
30
external filter for PLL2/soft start
HSMOD
31
input for EHT compensation (via horizontal size)
i.c.
32
internally connected; note 1: TDA4853
FOCUS
32
output for horizontal and vertical focus: TDA4854
Note
1. External connections to this pin are not allowed.
1999 Jul 13
6
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
handbook, halfpage
TDA4853; TDA4854
handbook, halfpage
HFLB 1
32 i.c.
HFLB 1
32 FOCUS
XRAY 2
31 HSMOD
XRAY 2
31 HSMOD
BOP 3
30 HPLL2
BOP 3
30 HPLL2
BSENS 4
29 HCAP
BSENS 4
29 HCAP
BIN 5
28 HREF
BIN 5
28 HREF
BDRV 6
27 HBUF
BDRV 6
27 HBUF
PGND 7
26 HPLL1
PGND 7
26 HPLL1
25 SGND
HDRV 8
HDRV 8
TDA4853
25 SGND
TDA4854
XSEL 9
24 VCAP
XSEL 9
24 VCAP
VCC 10
23 VREF
VCC 10
23 VREF
EWDRV 11
22 VAGC
EWDRV 11
22 VAGC
VOUT2 12
21 VSMOD
VOUT2 12
21 VSMOD
VOUT1 13
20 ASCOR
VOUT1 13
20 ASCOR
VSYNC 14
19 SDA
VSYNC 14
19 SDA
HSYNC 15
18 SCL
HSYNC 15
18 SCL
CLBL 16
17 HUNLOCK
CLBL 16
MGM066
17 HUNLOCK
MGM067
Fig.3 Pin configuration for TDA4853.
Fig.4 Pin configuration for TDA4854.
FUNCTIONAL DESCRIPTION
Vertical sync integrator
Horizontal sync separator and polarity correction
Normalized composite sync signals from HSYNC are
integrated on an internal capacitor in order to extract
vertical sync pulses. The integration time is dependent on
the horizontal oscillator reference current at HREF
(pin 28). The integrator output directly triggers the vertical
oscillator.
HSYNC (pin 15) is the input for horizontal synchronization
signals, which can be DC-coupled TTL signals (horizontal
or composite sync) and AC-coupled negative-going video
sync signals. Video syncs are clamped to 1.28 V and
sliced at 1.4 V. This results in a fixed absolute slicing level
of 120 mV related to top sync.
Vertical sync slicer and polarity correction
For DC-coupled TTL signals the input clamping current is
limited. The slicing level for TTL signals is 1.4 V.
Vertical sync signals (TTL) applied to VSYNC (pin 14) are
sliced at 1.4 V. The output signal of the sync slicer is
integrated on an internal capacitor to detect and normalize
the sync polarity. The output signals of vertical sync
integrator and sync normalizer are disjuncted before they
are fed to the vertical oscillator.
The separated sync signal (either video or TTL) is
integrated on an internal capacitor to detect and normalize
the sync polarity.
Normalized horizontal sync pulses are used as input
signals for the vertical sync integrator, the PLL1 phase
detector and the frequency-locked loop.
The presence of equalization pulses is allowed for correct
function of the PLL1 phase detector only in TV mode.
1999 Jul 13
7
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
The internal frequency detector then starts tuning the
oscillator. Very small DC currents at HPLL1 (pin 26) are
used to perform this tuning with a well defined change rate.
When coincidence between horizontal sync and oscillator
frequency is detected, the search mode is first replaced by
a soft-lock mode which lasts for the first part of the next
vertical period. The soft-lock mode is then replaced by a
normal PLL operation. This operation ensures smooth
tuning and avoids fast changes of horizontal frequency
during catching.
Video clamping/vertical blanking generator
The video clamping/vertical blanking signal at CLBL
(pin 16) is a two-level sandcastle pulse which is especially
suitable for video ICs such as the TDA488x family, but also
for direct applications in video output stages.
The upper level is the video clamping pulse, which is
triggered by the horizontal sync pulse. Either the leading or
trailing edge can be selected by setting control bit CLAMP
via the I2C-bus. The width of the video clamping pulse is
determined by an internal single-shot multivibrator.
In this concept it is not allowed to load HPLL1.
The frequency dependent voltage at this pin is fed
internally to HBUF (pin 27) via a sample-and-hold and
buffer stage. The sample-and-hold stage removes all
disturbances caused by horizontal sync or composite
vertical sync from the buffered voltage. An external
resistor connected between pins HBUF and HREF defines
the frequency range.
The lower level of the sandcastle pulse is the vertical
blanking pulse, which is derived directly from the internal
oscillator waveform. It is started by the vertical sync and
stopped with the start of the vertical scan. This results in
optimum vertical blanking. Two different vertical blanking
times are accessible, by control bit VBLK, via the I2C-bus.
Blanking will be activated continuously if one of the
following conditions is true:
Out-of-lock indication (pin HUNLOCK)
Soft start of horizontal and B+ drive [voltage at HPLL2
(pin 30) pulled down externally or by the I2C-bus]
Pin HUNLOCK is floating during search mode if no sync
pulses are applied, or if a protection condition is true.
All this can be detected by the microcontroller if a pull-up
resistor is connected to its own supply voltage.
PLL1 is unlocked while frequency-locked loop is in
search mode or if horizontal sync pulses are absent
No horizontal flyback pulses at HFLB (pin 1)
For an additional fast vertical blanking at grid 1 of the
picture tube a 1 V signal referenced to ground is available
at this output. The continuous protection blanking
(see Section “Video clamping/vertical blanking generator”)
is also available at this pin. Horizontal unlock blanking can
be switched off, by control bit BLKDIS via the I2C-bus
while vertical blanking is maintained.
X-ray protection is activated
Supply voltage at VCC (pin 10) is low (see Fig.25).
Horizontal unlock blanking can be switched off, by control
bit BLKDIS, via the I2C-bus while vertical blanking and
protection blanking is maintained.
Frequency-locked loop
TV mode
The frequency-locked loop can lock the horizontal
oscillator over a wide frequency range. This is achieved by
a combined search and PLL operation. The frequency
range is preset by two external resistors and the
f max
6.5
recommended maximum ratio is --------- = -------1
f min
In applications with TV signals the standard
frequency-to-voltage converter operation will be disturbed
by equalizing sync pulses and phase jumps occurring in
VCR signals. To avoid this, a TV mode has been
implemented. It can be accessed by choosing the
horizontal TV sync frequencies of 15.625 or 15.75 kHz as
the minimum frequency for the horizontal oscillator.
Applying TV signals will cause the frequency-to-voltage
converter to scan down to this frequency in normal
operation. If the control bit TVMOD is sent by the I2C-bus,
the HBUF output is clamped to 2.5 V and an internally
defined PLL1 control range of ±10% is established.
To return to standard operation of the
frequency-to-voltage converter the bit TVMOD has to be
reset. For an optimal operation with VCR signals the RC
combination at pin HPLL1 has to be switched externally.
This can, for instance, be a range from 15.625 to 90 kHz
with all tolerances included.
Without a horizontal sync signal the oscillator will be
free-running at fmin. Any change of sync conditions is
detected by the internal coincidence detector. A deviation
of more than 4% between horizontal sync and oscillator
frequency will switch the horizontal section into search
mode. This means that PLL1 control currents are switched
off immediately.
1999 Jul 13
TDA4853; TDA4854
8
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
The resistor RHBUFpar is calculated as the value of RHREF
and RHBUF in parallel. The formulae for RHBUF also takes
into account the voltage swing across this resistor
R HREF × R HBUFpar
R HBUF = ---------------------------------------------- × 0.8 = 805 Ω
R HREF – R HBUFpar
Horizontal oscillator
The horizontal oscillator is of the relaxation type and
requires a capacitor of 10 nF to be connected at HCAP
(pin 29). For optimum jitter performance the value of 10 nF
must not be changed.
The minimum oscillator frequency is determined by a
resistor connected between pin HREF and ground.
A resistor connected between pins HREF and HBUF
defines the frequency range.
PLL1 phase detector
The phase detector is a standard type using switched
current sources, which are independent of the horizontal
frequency. It compares the middle of the horizontal sync
with a fixed point on the oscillator sawtooth voltage.
The PLL1 loop filter is connected to HPLL1 (pin 26).
The reference current at pin HREF also defines the
integration time constant of the vertical sync integration.
Calculation of line frequency range
See also Section “Horizontal position adjustment and
corrections”.
The oscillator frequencies fmin and fmax must first be
calculated. This is achieved by adding the spread of the
relevant components to the highest and lowest sync
frequencies fsync(min) and fsync(max). The oscillator is driven
by the currents in RHREF and RHBUF.
Horizontal position adjustment and corrections
A linear adjustment of the relative phase between the
horizontal sync and the oscillator sawtooth (in PLL1 loop)
is achieved via register HPOS. Once adjusted, the relative
phase remains constant over the whole frequency range.
The following example is a 31.45 to 90 kHz application:
Table 1
Calculation of total spread
spread of
for fmax
for fmin
IC
±3%
±5%
CHCAP
±2%
±2%
RHREF, RHBUF
±2%
±2%
Total
±7%
±9%
Correction of pin unbalance and parallelogram is achieved
by modulating the phase between the oscillator sawtooth
and horizontal flyback (in loop PLL2) via registers
HPARAL and HPINBAL. If those asymmetric EW
corrections are performed in the deflection stage, both
registers can be disconnected from the horizontal phase
via control bit ACD. This does not change the output at
pin ASCOR.
Horizontal moire cancellation
Thus the typical frequency range of the oscillator in this
example is:
To achieve a cancellation of horizontal moire (also known
as ‘video moire’), the horizontal frequency is
divided-by-two to achieve a modulation of the horizontal
phase via PLL2. The amplitude is controlled by
register HMOIRE. To avoid a visible structure on screen
the polarity changes with half of the vertical frequency.
Control bit MOD disables the moire cancellation function.
f max = f sync ( max ) × 1.07 = 96.3 kHz
f sync ( min )
f min = ---------------------- = 28.9 kHz
1.09
The TV mode is centred around fmin with a control range of
±10%. Activation of the TV mode is only allowed between
15.625 and 35 kHz.
The resistors RHREF and RHBUFpar can be calculated using
the following formulae:
78 × kHz × k Ω
= 2.61 kΩ
R HREF = ----------------------------------------------------------------2
f min + 0.0012 × f min [ kHz ]
78 × kHz × k Ω
R HBUFpar = ------------------------------------------------------------------- = 726 Ω
2
f max + 0.0012 × f max [ kHz ]
1999 Jul 13
TDA4853; TDA4854
9
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
PLL2 phase detector
Output stage for line drive pulses [HDRV (pin 8)]
The PLL2 phase detector is similar to the PLL1 detector
and compares the line flyback pulse at HFLB (pin 1) with
the oscillator sawtooth voltage. The control currents are
independent of the horizontal frequency. The PLL2
detector thus compensates for the delay in the external
horizontal deflection circuit by adjusting the phase of the
HDRV (pin 8) output pulse.
An open-collector output stage allows direct drive of an
inverting driver transistor because of a low saturation
voltage of 0.3 V at 20 mA. To protect the line deflection
transistor, the output stage is disabled (floating) for a low
supply voltage at VCC (see Fig.25).
The duty cycle of line drive pulses is slightly dependent on
the actual horizontal frequency. This ensures optimum
drive conditions over the whole frequency range.
For the TDA4854 external modulation of the PLL2 phase
is not allowed, because this would disturb the start
advance of the horizontal focus parabola.
X-ray protection
The X-ray protection input XRAY (pin 2) provides a voltage
detector with a precise threshold. If the input voltage at
XRAY exceeds this threshold for a certain time then
control bit SOFTST is reset, which switches the IC into
protection mode. In this mode several pins are forced into
defined states:
Soft start and standby
If HPLL2 is pulled to ground by resetting the
register SOFTST, the horizontal output pulses, vertical
output currents and B+ control driver pulses will be
inhibited. This means that HDRV (pin 8), BDRV (pin 6),
VOUT1 (pin 13) and VOUT2 (pin 12) are floating in this
state. If HPLL2 is pulled to ground by an external DC
current, vertical output currents stay active while HDRV
(pin 8) and BDRV (pin 6) are in floating state. In both cases
the PLL2 and the frequency-locked loop are disabled,
CLBL (pin 16) provides a continuous blanking signal and
HUNLOCK (pin 17) is floating.
HUNLOCK (pin 17) is floating
The capacitor connected to HPLL2 (pin 30) is
discharged
Horizontal output stage (HDRV) is floating
B+ control driver stage (BDRV) is floating
Vertical output stages (VOUT1 and VOUT2) are floating
This option can be used for soft start, protection and
power-down modes. When the HPLL2 pin is released
again, an automatic soft start sequence on the horizontal
drive as well as on the B+ drive output will be performed
(see Figs 26 and 27).
CLBL provides a continuous blanking signal.
There are two different methods of restarting the IC:
1. XSEL (pin 9) is open-circuit or connected to ground.
The control bit SOFTST must be set to logic 1 via the
I2C-bus. The IC then returns to normal operation via
soft start.
A soft start can only be performed if the supply voltage for
the IC is a minimum of 8.6 V.
2. XSEL (pin 9) is connected to VCC via an external
resistor. The supply voltage of the IC must be switched
off for a certain period of time before the IC can be
restarted again using the standard power-on
procedure.
The soft start timing is determined by the filter capacitor at
HPLL2 (pin 30), which is charged with a constant current
during soft start. If the voltage at pin 30 (HPLL2) reaches
1.1 V, the vertical output currents are enabled. At 1.7 V the
horizontal driver stage generates very small output pulses.
The width of these pulses increases with the voltage at
HPLL2 until the final duty cycle is reached. The voltage at
HPLL2 increases further and performs a soft start at BDRV
(pin 6) as well. The voltage at HPLL2 continues to rise until
HPLL2 enters its normal operating range. The internal
charge current is now disabled. Finally PLL2 and the
frequency-locked loop are activated. If both functions
reach normal operation, HUNLOCK (pin 17) switches from
the floating status to normal vertical blanking, and
continuous blanking at CLBL (pin 16) is removed.
1999 Jul 13
10
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
Vertical oscillator and amplitude control
Adjustment of vertical size, VGA overscan and EHT
compensation
This stage is designed for fast stabilization of vertical size
after changes in sync frequency conditions.
The amplitude of the differential output currents at VOUT1
and VOUT2 can be adjusted via register VSIZE.
Register VOVSCN can activate a +17% step in vertical
size for the VGA350 mode.
The free-running frequency ffr(V) is determined by the
resistor RVREF connected to pin 23 and the capacitor
CVCAP connected to pin 24. The value of RVREF is not only
optimized for noise and linearity performance in the whole
vertical and EW section, but also influences several
internal references. Therefore the value of RVREF must not
be changed.
VSMOD (pin 21) can be used for a DC controlled EHT
compensation of vertical size by correcting the differential
output currents at VOUT1 and VOUT2. The EW
waveforms, (vertical focus), pin unbalance and
parallelogram corrections are not affected by VSMOD.
Capacitor CVCAP should be used to select the free-running
frequency of the vertical oscillator in accordance with the
1
following formula: f fr ( V ) = ----------------------------------------------------------10.8 × R VREF × C VCAP
The adjustments for vertical size and vertical position also
affect the waveforms of the horizontal pincushion, vertical
linearity (S-correction), vertical linearity balance, focus
parabola, pin unbalance and parallelogram correction.
The result of this interaction is that no re-adjustment of
these parameters is necessary after an adjustment of
vertical picture size or position.
To achieve a stabilized amplitude the free-running
frequency ffr(V), without adjustment, should be at least 10%
lower than the minimum trigger frequency.
The contributions shown in Table 2 can be assumed.
Table 2
Adjustment of vertical position, vertical linearity and
vertical linearity balance
Calculation of ffr(V) total spread
Register VPOS provides a DC shift at the sawtooth
outputs VOUT1 and VOUT2 (pins 13 and 12) and the EW
drive output EWDRV (pin 11) in such a way that the whole
picture moves vertically while maintaining the correct
geometry.
Contributing elements
Minimum frequency offset between ffr(V) and
lowest trigger frequency
10%
Spread of IC
±3%
Spread of RVREF
±1%
Spread of CVCAP
±5%
Total
19%
Register VLIN is used to adjust the amount of vertical
S-correction in the output signal. This function can be
switched off by control bit VSC.
Register VLINBAL is used to correct the unbalance of the
vertical S-correction in the output signal. This function can
be switched off by control bit VLC.
Result for 50 to 160 Hz application:
50 Hz
f fr ( V ) = --------------- = 42 Hz
1.19
Adjustment of vertical moire cancellation
The AGC of the vertical oscillator can be disabled by
setting control bit AGCDIS via the I2C-bus. A precise
external current has to be injected into VCAP (pin 24) to
obtain the correct vertical size. This special application
mode can be used when the vertical sync pulses are
serrated (shifted); this condition is found in some display
modes, e.g. when using a 100 Hz up converter for video
signals.
To achieve a cancellation of vertical moire (also known as
‘scan moire’) the vertical picture position can be modulated
by half the vertical frequency. The amplitude of the
modulation is controlled by register VMOIRE and can be
switched off via control bit MOD.
Application hint: VAGC (pin 22) has a high input
impedance during scan. Therefore, the pin must not be
loaded externally otherwise non-linearities in the vertical
output currents may occur due to the changing charge
current during scan.
1999 Jul 13
TDA4853; TDA4854
11
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
Horizontal pincushion (including horizontal size,
corner correction and trapezium correction)
V HSIZE
V HSIZE + V HEHT  1 – ---------------
14.4 V
g(HSIZE, HSMOD) = 1 – -------------------------------------------------------------------------14.4 V
EWDRV (pin 11) provides a complete EW drive waveform.
The components horizontal pincushion, horizontal size,
corner correction and trapezium correction are controlled
by the registers HPIN, HSIZE, HCOR and HTRAP.
HTRAP can be set to zero by control bit VPC.
I HREF
h ( I HREF ) = ------------------------------I HREF
f = 70kHz
Two different modes of operation can be chosen for the
EW output waveform via control bit FHMULT:
The pincushion (EW parabola) amplitude, corner and
trapezium correction track with the vertical picture size
(VSIZE) and also with the adjustment for vertical picture
position (VPOS). The corner correction does not track with
the horizontal pincushion (HPIN).
1. Mode 1
Horizontal size is controlled via register HSIZE and
causes a DC shift at the EWDRV output. The complete
waveform is also multiplied internally by a signal
proportional to the line frequency [which is detected
via the current at HREF (pin 28)]. This mode is to be
used for driving EW diode modulator stages which
require a voltage proportional to the line frequency.
Further the horizontal pincushion amplitude, corner and
trapezium correction track with the horizontal picture size,
which is adjusted via register HSIZE and the analog
modulation input HSMOD.
If the DC component in the EWDRV output signal is
increased via HSIZE or IHSMOD, the pincushion, corner and
trapezium component of the EWDRV output will be
V HSIZE
V HSIZE + V HEHT  1 – ---------------
14.4 V
reduced by a factor of 1 – ------------------------------------------------------------------------14.4
2. Mode 2
The EW drive waveform does not track with the line
frequency. This mode is to be used for driving EW
modulators which require a voltage independent of the
line frequency.
Output stage for asymmetric correction waveforms
[ASCOR (pin 20)]
The value 14.4 V is a virtual voltage for calculation only.
The output pin can not reach this value, but the gain (and
DC bias) of the external application should be such that the
horizontal deflection is reduced to zero when EWDRV
reaches 14.4 V.
This output is designed as a voltage output for
superimposed waveforms of vertical parabola and
sawtooth. The amplitude and polarity of both signals can
be changed via registers HPARAL and HPINBAL.
HSMOD can be used for a DC controlled EHT
compensation by correcting horizontal size, horizontal
pincushion, corner and trapezium. The control range at
this pin tracks with the actual value of HSIZE. For an
increasing DC component VHSIZE in the EWDRV output
signal, the DC component VHEHT caused by IHSMOD will be
Application hint: The TDA4854 offers two possibilities to
control registers HPINBAL and HPARAL.
1. Control bit ACD = 1
The two registers now control the horizontal phase by
means of internal modulation of the PLL2 horizontal
phase control. The ASCOR output (pin 20) can be left
unused, but it will always provide an output signal
because the ASCOR output stage is not influenced by
the control bit ACD.
V HSIZE
reduced by a factor of 1 – ---------------- as shown in the equation
14.4 V
above.
The whole EWDRV voltage is calculated as follows:
VEWDRV = 1.2 V + [VHSIZE + VHEHT × f(HSIZE) + (VHPIN +
VHCOR + VHTRAP) × g(HSIZE, HSMOD)] × h(IHREF)
2. Control bit ACD = 0
The internal modulation via PLL2 is disconnected.
In order to obtain the required effect on the screen,
pin ASCOR must now be fed to the DC amplifier which
controls the DC shift of the horizontal deflection. This
option is useful for applications which already use a
DC shift transformer.
Where:
I HSMOD
V HEHT = -------------------- × 0.69
120 µA
V HSIZE
f(HSIZE) = 1 – ---------------14.4 V
1999 Jul 13
TDA4853; TDA4854
If the tube does not need HPINBAL and HPARAL, then pin
ASCOR can be used for other purposes, i.e. for a simple
dynamic convergence.
12
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
• Boost converter in feedback mode (see Fig.23)
TDA4854: dynamic focus section [FOCUS (pin 32)]
In this application the OTA is used as an error amplifier
with a limited output voltage range. The flip-flop is set on
the rising edge of the signal at HDRV. A reset will be
generated when the voltage at BSENS, taken from the
current sense resistor, exceeds the voltage at BOP.
This section generates a complete drive signal for dynamic
focus applications. The amplitude of the horizontal
parabola is internally stabilized, thus it is independent of
the horizontal frequency. The amplitude can be adjusted
via register HFOCUS. Changing horizontal size may
require a correction of HFOCUS. To compensate for the
delay in external focus amplifiers a ‘pre-correction’ for the
phase of the horizontal parabola has been implemented.
The amplitude of the vertical parabola is independent of
frequency and tracks with all vertical adjustments.
The amplitude can be adjusted via register VFOCUS.
FOCUS (pin 32) is designed as a voltage output for the
superimposed vertical and horizontal parabolas.
If no reset is generated within a line period. The rising
edge of the next HDRV pulse forces the flip-flop to reset.
The flip-flop is set immediately after the voltage at
BSENS has dropped below the threshold voltage
VRESTART(BSENS).
• Buck converter in feed forward mode (see Fig.24)
This application uses an external RC combination at
BSENS to provide a pulse width which is independent
from the horizontal frequency. The capacitor is charged
via an external resistor and discharged by the internal
discharge circuit. For normal operation the discharge
circuit is activated when the flip-flop is reset by the
internal voltage comparator. The capacitor will now be
discharged with a constant current until the internally
controlled stop level VSTOP(BSENS) is reached. This level
will be maintained until the rising edge of the next HDRV
pulse sets the flip-flop again and disables the discharge
circuit.
B+ control function block
The B+ control function block of the TDA4853; TDA4854
consists of an Operational Transconductance Amplifier
(OTA), a voltage comparator, a flip-flop and a discharge
circuit. This configuration allows easy applications for
different B+ control concepts. See also Application Note
AN96052: “B+ converter Topologies for Horizontal
Deflection and EHT with TDA4855/58”.
GENERAL DESCRIPTION
If no reset is generated within a line period, the rising
edge of the next HDRV pulse automatically starts the
discharge sequence and resets the flip-flop. When the
voltage at BSENS reaches the threshold voltage
VRESTART(BSENS), the discharge circuit will be disabled
automatically and the flip-flop will be set immediately.
This behaviour allows a definition of the maximum duty
cycle of the B+ control drive pulse by the relationship of
charge current to discharge current.
The non-inverting input of the OTA is connected internally
to a high precision reference voltage. The inverting input is
connected to BIN (pin 5). An internal clamping circuit limits
the maximum positive output voltage of the OTA.
The output itself is connected to BOP (pin 3) and to the
inverting input of the voltage comparator.
The non-inverting input of the voltage comparator can be
accessed via BSENS (pin 4).
B+ drive pulses are generated by an internal flip-flop and
fed to BDRV (pin 6) via an open-collector output stage.
This flip-flop is set at the rising edge of the signal at HDRV
(pin 8). The falling edge of the output signal at BDRV has
a defined delay of td(BDRV) to the rising edge of the HDRV
pulse (see Fig.23). When the voltage at BSENS exceeds
the voltage at BOP, the voltage comparator output resets
the flip-flop and, therefore, the open-collector stage at
BDRV is floating again.
Supply voltage stabilizer, references, start-up
procedures and protection functions
The TDA4853; TDA4854 provides an internal supply
voltage stabilizer for excellent stabilization of all internal
references. An internal gap reference, especially designed
for low-noise, is the reference for the internal horizontal
and vertical supply voltages. All internal reference currents
and drive current for the vertical output stage are derived
from this voltage via external resistors.
An internal discharge circuit allows a well defined
discharge of capacitors at BSENS. BDRV is active at a
LOW-level output voltage (see Figs 23 and 24), thus it
requires an external inverting driver stage.
If either the supply voltage is below 8.3 V or no data from
the I2C-bus has been received after power-up, the internal
soft start and protection functions do not allow any of those
outputs [HDRV, BDRV, VOUT1, VOUT2 and HUNLOCK
(see Fig.25)] to be active.
The B+ function block can be used for B+ deflection
modulators in many different ways. Two popular
application combinations are as follows:
1999 Jul 13
TDA4853; TDA4854
13
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
For supply voltages below 8.3 V the internal I2C-bus will
not generate an acknowledge and the IC is in standby
mode. This is because the internal protection circuit has
generated a reset signal for the soft start
register SOFTST. Above 8.3 V data is accepted and all
registers can be loaded. If the register SOFTST has
received a set from the I2C-bus, the internal soft start
procedure is released, which activates all mentioned
outputs.
When the protection mode is active, several pins of the
TDA4853; TDA4854 are forced into a defined state:
If during normal operation the supply voltage has dropped
below 8.1 V, the protection mode is activated and
HUNLOCK (pin 17) changes to the protection status and is
floating. This can be detected by the microcontroller.
VOUT1 and VOUT2 (vertical outputs) are floating
HDRV (horizontal driver output) is floating
BDRV (B+ control driver output) is floating
HUNLOCK (indicates, that the frequency-to-voltage
converter is out of lock) is floating (HIGH via external
pull-up resistor)
CLBL provides a continuous blanking signal
The capacitor at HPLL2 is discharged.
If the soft start procedure is activated via the I2C-bus, all of
these actions will be performed in a well defined sequence
(see Figs 25 and 26).
This protection mode has been implemented in order to
protect the deflection stages and the picture tube during
start-up, shut-down and fault conditions. This protection
mode can be activated as shown in Table 3.
Table 3
Activation of protection mode
ACTIVATION
RESET
Low supply voltage at
pin 10
increase supply voltage;
reload registers;
soft start via I2C-bus
Power dip, below 8.1 V
reload registers;
soft start via I2C-bus
X-ray protection (pin 2)
triggered, XSEL (pin 9) is
open-circuit or connected
to ground
reload registers;
soft start via I2C-bus
X-ray protection (pin 2)
triggered, XSEL (pin 9)
connected to VCC via an
external resistor
switch VCC off and on
again, reload registers;
soft start via I2C-bus
HPLL2 (pin 30) externally
pulled to ground
release pin 30
1999 Jul 13
14
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
LIMITING VALUES
In accordance with the Absolute Maximum Rating System (IEC 134); all voltages measured with respect to ground.
SYMBOL
PARAMETER
VCC
supply voltage
Vi(n)
input voltage for pins:
Vo(n)
CONDITIONS
MIN.
MAX.
−0.5
UNIT
+16
V
BIN
−0.5
+6.0
V
HSYNC, VSYNC, VREF, HREF, VSMOD and HSMOD
−0.5
+6.5
V
SDA and SCL
−0.5
+8.0
V
XRAY
−0.5
+8.0
V
VOUT2, VOUT1 and HUNLOCK
−0.5
+6.5
V
BDRV and HDRV
−0.5
+16
V
output voltage for pins:
VI/O(n)
input/output voltages at pins BOP and BSENS
−0.5
+6.0
V
Io(HDRV)
horizontal driver output current
−
100
mA
Ii(HFLB)
horizontal flyback input current
−10
+10
mA
Io(CLBL)
video clamping pulse/vertical blanking output current
−
−10
mA
Io(BOP)
B+ control OTA output current
−
1
mA
Io(BDRV)
B+ control driver output current
−
50
mA
Io(EWDRV)
EW driver output current
−
−5
mA
Io(FOCUS)
focus driver output current
−
−5
mA
Tamb
operating ambient temperature
−20
+70
°C
Tj
junction temperature
−
150
°C
Tstg
storage temperature
−55
+150
°C
VESD
electrostatic discharge for all pins
note 1
−150
+150
V
note 2
−2000 +2000 V
Notes
1. Machine model: 200 pF; 0.75 µH; 10 Ω.
2. Human body model: 100 pF; 7.5 µH; 1500 Ω.
THERMAL CHARACTERISTICS
SYMBOL
Rth(j-a)
PARAMETER
CONDITIONS
thermal resistance from junction to ambient
in free air
VALUE
UNIT
55
K/W
QUALITY SPECIFICATION
In accordance with “URF-4-2-59/601”; EMC emission/immunity test in accordance with “DIS 1000 4.6” (IEC 801.6).
SYMBOL
VEMC
PARAMETER
CONDITIONS
MIN.
TYP.
MAX.
emission test
note 1
−
1.5
−
mV
immunity test
note 1
−
2.0
−
V
Note
1. Tests are performed with application reference board. Tests with other boards will have different results.
1999 Jul 13
UNIT
15
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
CHARACTERISTICS
VCC = 12 V; Tamb = 25 °C; peripheral components in accordance with Figs 1 and 2; unless otherwise specified.
SYMBOL
PARAMETER
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Horizontal sync separator
INPUT CHARACTERISTICS FOR DC-COUPLED TTL SIGNALS: PIN HSYNC
Vi(HSYNC)
sync input signal voltage
1.7
−
−
V
VHSYNC(sl)
slicing voltage level
1.2
1.4
1.6
V
tr(HSYNC)
rise time of sync pulse
10
−
500
ns
tf(HSYNC)
fall time of sync pulse
10
−
500
ns
tW(HSYNC)(min)
minimum width of sync pulse
0.7
−
−
µs
Ii(HSYNC)
input current
VHSYNC = 0.8 V
−
−
−200
µA
VHSYNC = 5.5 V
−
−
10
µA
INPUT CHARACTERISTICS FOR AC-COUPLED VIDEO SIGNALS (SYNC-ON-VIDEO, NEGATIVE SYNC POLARITY)
VHSYNC
sync amplitude of video input
signal voltage
Rsource = 50 Ω
−
300
−
mV
VHSYNC(sl)
slicing voltage level
(measured from top sync)
Rsource = 50 Ω
90
120
150
mV
Vclamp(HSYNC)
top sync clamping voltage level Rsource = 50 Ω
1.1
1.28
1.5
V
Ich(HSYNC)
charge current for coupling
capacitor
1.7
2.4
3.4
µA
tW(HSYNC)(min)
minimum width of sync pulse
0.7
−
−
µs
Rsource(max)
maximum source resistance
duty cycle = 7%
−
−
1500
Ω
Ri(diff)(HSYNC)
differential input resistance
during sync
−
80
−
Ω
VHSYNC > Vclamp(HSYNC)
Automatic polarity correction for horizontal sync
tP ( H )
-----------tH
horizontal sync pulse width
related to line period
−
−
25
%
td(HPOL)
delay time for changing polarity
0.3
−
1.8
ms
fH = 15.625 kHz;
IHREF = 0.52 mA
14
20
26
µs
fH = 31.45 kHz;
IHREF = 1.052 mA
7
10
13
µs
fH = 64 kHz;
IHREF = 2.141 mA
3.9
5.7
6.5
µs
fH = 100 kHz;
IHREF = 3.345 mA
2.5
3.8
4.5
µs
1.7
−
−
V
1.2
1.4
1.6
V
−
−
±10
µA
Vertical sync integrator
tint(V)
integration time for generation
of a vertical trigger pulse
Vertical sync slicer (DC-coupled, TTL compatible): pin VSYNC
Vi(VSYNC)
sync input signal voltage
VVSYNC(sl)
slicing voltage level
Ii(VSYNC)
input current
1999 Jul 13
0 V < VSYNC < 5.5 V
16
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Automatic polarity correction for vertical sync
tW(VSYNC)(max)
maximum width of vertical sync
pulse
−
−
400
µs
td(VPOL)
delay time for changing polarity
0.45
−
1.8
ms
0.6
0.7
0.8
µs
Video clamping/vertical blanking output: pin CLBL
tclamp(CLBL)
width of video clamping pulse
measured at VCLBL = 3 V
Vclamp(CLBL)
top voltage level of video
clamping pulse
4.32
4.75
5.23
V
TCclamp
temperature coefficient of
Vclamp(CLBL)
−
4
−
mV/K
STPSclamp
steepness of slopes for
clamping pulse
RL = 1 MΩ; CL = 20 pF
−
50
−
ns/V
td(HSYNCt-CLBL)
delay between trailing edge of
horizontal sync and start of
video clamping pulse
−
130
−
ns
tclamp1(max)
maximum duration of video
clamping pulse referenced to
end of horizontal sync
clamping pulse triggered
on trailing edge of
horizontal sync;
control bit CLAMP = 0;
measured at VCLBL = 3 V
−
−
1.0
µs
td(HSYNCl-CLBL)
delay between leading edge of
horizontal sync and start of
video clamping pulse
−
300
−
ns
tclamp2(max)
maximum duration of video
clamping pulse referenced to
end of horizontal sync
−
−
0.15
µs
Vblank(CLBL)
top voltage level of vertical
blanking pulse
notes 1 and 2
1.7
1.9
2.1
V
tblank(CLBL)
width of vertical blanking pulse
at pins CLBL and HUNLOCK
control bit VBLK = 0
220
260
300
µs
TCblank
temperature coefficient of
Vblank(CLBL)
Vscan(CLBL)
output voltage during vertical
scan
TCscan
clamping pulse triggered
on leading edge of
horizontal sync;
control bit CLAMP = 1;
measured at VCLBL = 3 V
305
350
395
µs
−
2
−
mV/K
0.59
0.63
0.67
V
temperature coefficient of
Vscan(CLBL)
−
−2
−
mV/K
Isink(CLBL)
internal sink current
2.4
−
−
mA
IL(CLBL)
external load current
−
−
−3.0
mA
1999 Jul 13
control bit VBLK = 1
ICLBL = 0
17
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Horizontal oscillator: pins HCAP and HREF
RHBUF = ∞;
RHREF = 2.4 kΩ;
CHCAP = 10 nF; note 3
30.53
31.45
32.39
kHz
spread of free-running
frequency (excluding spread of
external components)
−
−
±3.0
%
TCfr
temperature coefficient of
free-running frequency
−100
0
+100
10−6/K
fH(max)
maximum oscillator frequency
−
−
130
kHz
VHREF
voltage at input for reference
current
2.43
2.55
2.68
V
−
−
250
mV
ffr(H)
free-running frequency without
PLL1 action (for testing only)
∆ffr(H)
Unlock blanking detection: pin HUNLOCK
Vscan(HUNLOCK)
low level voltage of HUNLOCK
saturation voltage in case
of locked PLL1; internal
sink current = 1 mA
Vblank(HUNLOCK)
blanking level of HUNLOCK
external load current = 0
0.9
1
1.1
V
TCblank
temperature coefficient of
Vblank(HUNLOCK)
−
−0.9
−
mV/K
TCsink
temperature coefficient of
Isink(HUNLOCK)
−
0.15
−
%/K
Isink(int)
internal sink current
1.4
2.0
2.6
mA
IL(max)
maximum external load current VHUNLOCK = 1 V
−
−
−2
mA
IL
leakage current
−
−
±5
µA
−
−
25
%
−
40
80
ms
−
15
−
µA
for blanking pulses;
PLL1 locked
VHUNLOCK = 5 V in case of
unlocked PLL1 and/or
protection active
PLL1 phase comparator and frequency-locked loop: pins HPLL1 and HBUF
tW(HSYNC)(max)
maximum width of horizontal
sync pulse (referenced to line
period)
tlock(HPLL1)
total lock-in time of PLL1
Ictrl(HPLL1)
control currents
notes 4 and 5
locked mode, level 1
−
145
−
µA
minimum horizontal
frequency
−
2.5
−
V
maximum horizontal
frequency
−
0.5
−
V
locked mode, level 2
VHBUF
1999 Jul 13
buffered f/v voltage at HBUF
(pin 27)
18
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Phase adjustments and corrections via PLL1 and PLL2
HPOS
HPINBAL
HPARAL
HMOIRE
HMOIREoff
horizontal position (referenced
to horizontal period)
horizontal pin unbalance
correction via HPLL2
(referenced to horizontal
period)
horizontal parallelogram
correction (referenced to
horizontal period)
register HPOS = 0
−
−13
−
%
register HPOS = 127
−
0
−
%
register HPOS = 255
−
13
−
%
register HPINBAL = 0;
−
control bit HPC = 0; note 6
−0.8
−
%
register HPINBAL = 15;
−
control bit HPC = 0; note 6
0.8
−
%
register HPINBAL = X;
−
control bit HPC = 1; note 6
0
−
%
register HPARAL = 0;
−
control bit HBC = 0; note 6
−0.8
−
%
register HPARAL = 15;
−
control bit HBC = 0; note 6
0.8
−
%
register HPARAL = X;
−
control bit HBC = 1; note 6
0
−
%
relative modulation of
horizontal position by 0.5fH;
phase alternates with 0.5fV
register HMOIRE = 0;
control bit MOD = 0
−
0
−
%
register HMOIRE = 31;
control bit MOD = 0
−
0.05
−
%
moire cancellation off
control bit MOD = 1
−
0
−
%
maximum advance;
register HPINBAL = 07;
register HPARAL = 07
36
−
−
%
minimum advance;
register HPINBAL = 07;
register HPARAL = 07
−
7
−
%
PLL2 phase detector: pins HFLB and HPLL2
φPLL2
PLL2 control (advance of
horizontal drive with respect to
middle of horizontal flyback)
Ictrl(PLL2)
PLL2 control current
−
75
−
µA
ΦPLL2
relative sensitivity of PLL2
phase shift related to horizontal
period
−
28
−
mV/%
VPROT(PLL2)(max)
maximum voltage for PLL2
protection mode/soft start
−
4.4
−
V
Ich(PLL2)
charge current for external
capacitor during soft start
VHPLL2 < 3.7 V
−
1
−
µA
HORIZONTAL FLYBACK INPUT: PIN HFLB
Vpos(HFLB)
positive clamping voltage
IHFLB = 5 mA
−
5.5
−
V
Vneg(HFLB)
negative clamping voltage
IHFLB = −1 mA
−
−0.75
−
V
Ipos(HFLB)
positive clamping current
−
−
6
mA
Ineg(HFLB)
negative clamping current
−
−
−2
mA
Vsl(HFLB)
slicing level
−
2.8
−
V
1999 Jul 13
19
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Output stage for line driver pulses: pin HDRV
OPEN-COLLECTOR OUTPUT STAGE
Vsat(HDRV)
saturation voltage
ILO(HDRV)
output leakage current
IHDRV = 20 mA
−
−
0.3
V
IHDRV = 60 mA
−
−
0.8
V
VHDRV = 16 V
−
−
10
µA
IHDRV = 20 mA;
42
fH = 31.45 kHz; see Fig.16
45
48
%
IHDRV = 20 mA;
fH = 58 kHz; see Fig.16
45.5
48.5
51.5
%
IHDRV = 20 mA;
fH = 110 kHz; see Fig.16
49
52
55
%
6.22
6.39
6.56
V
AUTOMATIC VARIATION OF DUTY CYCLE
tHDRV(OFF)/tH
relative tOFF time of HDRV
output; measured at
VHDRV = 3 V; HDRV duty cycle
is modulated by the relation
IHREF/IVREF
X-ray protection: pins XRAY and XSEL
VXRAY(sl)
slicing voltage level for latch
tW(XRAY)(min)
minimum width of trigger pulse
Ri(XRAY)
input resistance at pin 2
XRAYrst
reset of X-ray latch
−
−
30
µs
VXRAY < 6.38 V + VBE
500
−
−
kΩ
VXRAY > 6.38 V + VBE
−
5
−
kΩ
standby mode
−
5
−
kΩ
pin 9 open-circuit or
connected to GND
set control bit SOFTST via
the I2C-bus
−
pin 9 connected to VCC via switch off VCC then re-apply −
RXSEL
VCC
VCC(XRAY)(min)
minimum supply voltage for
correct function of the X-ray
latch
pin 9 connected to VCC via −
RXSEL
−
4
V
VCC(XRAY)(max)
maximum supply voltage for
reset of the X-ray latch
pin 9 connected to VCC via 2
RXSEL
−
−
V
RXSEL
external resistor at pin 9
no reset via I2C-bus
−
130
kΩ
56
Vertical oscillator [oscillator frequency in application without adjustment of free-running frequency ffr(V)]
ffr(V)
free-running frequency
RVREF = 22 kΩ;
CVCAP = 100 nF
fcr(V)
vertical frequency catching
range
constant amplitude; note 7 50
VVREF
voltage at reference input for
vertical oscillator
td(scan)
delay between trigger pulse
and start of ramp at VCAP
(pin 24) (width of vertical
blanking pulse)
amplitude control current
IVAGC
1999 Jul 13
42
43.3
Hz
−
160
Hz
−
3.0
−
V
control bit VBLK = 0
220
260
300
µs
control bit VBLK = 1
305
350
395
µs
control bit AGCDIS = 0
±120
±200
±300
µA
control bit AGCDIS = 1
−
0
−
µA
20
40
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
CVAGC
PARAMETER
TDA4853; TDA4854
CONDITIONS
external capacitor at VAGC
(pin 22)
MIN.
150
TYP.
MAX.
UNIT
−
220
nF
Differential vertical current outputs
ADJUSTMENT OF VERTICAL SIZE INCLUDING VGA AND EHT COMPENSATION; see Fig.5
VSIZE
VSIZEVGA
VSMODEHT
Ii(VSMOD)
register VSIZE = 0;
bit VOVSCN = 0; note 8
−
60
−
%
register VSIZE = 127;
bit VOVSCN = 0; note 8
−
100
−
%
vertical size with VGA overscan register VSIZE = 0;
(referenced to nominal vertical bit VOVSCN = 1; note 8
size)
register VSIZE = 127;
bit VOVSCN = 1; note 8
−
70
−
%
115.9
116.8
117.7
%
EHT compensation on vertical
size via VSMOD (pin 21)
(referenced to 100% vertical
size)
IVSMOD = 0
−
0
−
%
IVSMOD = −120 µA
−
−7
−
%
input current (pin 21)
VSMOD = 0
−
0
−
µA
VSMOD = −7%
−
−120
−
µA
300
−
500
Ω
vertical size without VGA
overscan (referenced to
nominal vertical size)
Ri(VSMOD)
input resistance
Vref(VSMOD)
reference voltage at input
fro(VSMOD)
roll-off frequency (−3 dB)
−
5.0
−
V
IVSMOD = −60 µA
+ 15 µA (RMS)
1
−
−
MHz
register VPOS = 0;
control bit VPC = 0
−
−11.5
−
%
register VPOS = 127;
control bit VPC = 0
−
11.5
−
%
register VPOS = X;
control bit VPC = 1
−
0
−
%
register VLIN = 0;
−
control bit VSC = 0; note 8
2
−
%
register VLIN = 15;
−
control bit VSC = 0; note 8
46
−
%
register VLIN = X;
−
control bit VSC = 1; note 8
0
−
%
−
−
±0.7
%
ADJUSTMENT OF VERTICAL POSITION; see Fig.6
VPOS
vertical position (referenced to
100% vertical size)
ADJUSTMENT OF VERTICAL LINEARITY; see Fig.7
VLIN
δVLIN
1999 Jul 13
vertical linearity (S-correction)
symmetry error of S-correction
maximum VLIN
21
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
ADJUSTMENT OF VERTICAL LINEARITY BALANCE; see Fig.8
VLINBAL
VMOIRE
vertical linearity balance
(referenced to 100% vertical
size)
register VLINBAL = 0;
−3.3
control bit VLC = 0; note 8
−2.5
−1.7
%
register VLINBAL = 15;
1.7
control bit VLC = 0; note 8
2.5
3.3
%
register VLINBAL = X;
−
control bit VLC = 1; note 8
0
−
%
modulation of vertical picture
position by 1⁄2 vertical
frequency (related to 100%
vertical size)
register VMOIRE = 0;
control bit MOD = 0
−
0
−
%
register VMOIRE = 31;
control bit MOD = 0
−
0.08
−
%
moire cancellation off
control bit MOD = 1
−
0
−
%
0.76
0.85
0.94
mA
Vertical output stage: pins VOUT1 and VOUT2; see Fig.29
∆IVOUT = IVOUT1 − IVOUT2;
nominal settings; note 8
∆IVOUT(nom)(p-p)
nominal differential output
current (peak-to-peak value)
Io(VOUT)(max)
maximum output current at pins control bit VOVSCN = 1
VOUT1 and VOUT2
0.54
0.6
0.66
mA
VVOUT
allowed voltage at outputs
0
−
4.2
V
δIos(vert)(max)
maximum offset error of vertical nominal settings; note 8
output currents
−
−
±2.5
%
δIlin(vert)(max)
maximum linearity error of
vertical output currents
−
−
±1.5
%
1.05
1.2
1.35
V
nominal settings; note 8
EW drive output
EW DRIVE OUTPUT STAGE: PIN EWDRV; see Figs 9 to 12
bottom output voltage at pin
EWDRV (internally stabilized)
register HPIN = 0;
register HCOR = 04;
register HTRAP = 08;
register HSIZE = 255
Vo(EWDRV)(max)
maximum output voltage
note 9
7.0
−
−
V
IL(EWDRV)
load current
−
−
±2
mA
TCEWDRV
temperature coefficient of
output signal
−
−
600
10−6/K
VHPIN(EWDRV)
horizontal pincushion voltage
Vconst(EWDRV)
VHCOR(EWDRV)
1999 Jul 13
horizontal corner correction
voltage
−
0.04
−
V
register HPIN = 63; note 8 −
1.42
−
V
register HCOR = 0;
−
control bit VSC = 0; note 8
0.08
−
V
register HCOR = 31;
−
control bit VSC = 0; note 8
−0.64
−
V
register HCOR = X;
−
control bit VSC = 1; note 8
0
−
V
register HPIN = 0; note 8
22
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
VHTRAP(EWDRV)
PARAMETER
horizontal trapezium correction
voltage
TDA4853; TDA4854
CONDITIONS
MIN.
TYP.
MAX.
UNIT
register HTRAP = 15;
−
control bit VPC = 0; note 8
−0.33
−
V
register HTRAP = 0;
−
control bit VPC = 0; note 8
0.33
−
V
register HTRAP = X;
−
control bit VPC = 1; note 8
0
−
V
0.13
−
V
−
VHSIZE(EWDRV)
horizontal size voltage
3.6
−
V
VHEHT(EWDRV)
EHT compensation on
horizontal size via HSMOD
(pin 31)
IHSMOD = 0; note 8
−
0.69
−
V
IHSMOD = −120 µA; note 8
−
0.02
−
V
Ii(HSMOD)
input current (pin 31)
VHEHT = 0.02 V
−
0
−
µA
Ri(HSMOD)
input resistance
Vref(HSMOD)
reference voltage at input
fro(HSMOD)
roll-off frequency (−3 dB)
register HSIZE = 255;
note 8
register HSIZE = 0; note 8 −
−
−120
−
µA
300
−
500
Ω
IHSMOD = 0
−
5.0
−
V
IHSMOD = −60 µA
+ 15 µA (RMS)
1
−
−
MHz
15
−
80
kHz
IHREF = 1.052 mA;
fH = 31.45 kHz;
control bit FHMULT = 1;
note 10
−
0.72
−
V
IHREF = 2.341 mA;
fH = 70 kHz;
control bit FHMULT = 1;
note 10
−
1.42
−
V
function disabled;
control bit FHMULT = 0;
note 10
−
1.42
−
V
−
−
8
%
register HPARAL = 0;
−
control bit HPC = 0; note 8
−0.825
−
V
register HPARAL = 15;
−
control bit HPC = 0; note 8
0.825
−
V
register HPARAL = X;
−
control bit HPC = 1; note 8
0.05
−
V
VHEHT = 0.69 V
TRACKING OF EWDRV OUTPUT SIGNAL WITH HORIZONTAL FREQUENCY PROPORTIONAL VOLTAGE
fH(MULTI)
horizontal frequency range for
tracking
VPAR(EWDRV)
parabola amplitude at EWDRV
(pin 11)
LEEWDRV
linearity error of horizontal
frequency tracking
Output for asymmetric EW corrections: pin ASCOR
VHPARAL(ASCOR)
1999 Jul 13
vertical sawtooth voltage for
EW parallelogram correction
23
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
VHPINBAL(ASCOR)
PARAMETER
TDA4853; TDA4854
CONDITIONS
MIN.
vertical parabola voltage for pin register HPINBAL = 0;
−
unbalance correction
control bit HBC = 0; note 8
TYP.
MAX.
UNIT
−1.0
−
V
register HPINBAL = 15;
−
control bit HBC = 0; note 8
1.0
−
V
register HPINBAL = X;
−
control bit HBC = 1; note 8
0.05
−
V
Vo(ASCOR)(max)(p-p) maximum output voltage swing
(peak-to-peak value)
−
4
−
V
Vo(ASCOR)(max)
maximum output voltage
−
6.5
−
V
Vc(ASCOR)
centre voltage
−
4.0
−
V
Vo(ASCOR)(min)
minimum output voltage
−
1.9
−
V
Io(ASCOR)(max)
maximum output current
VASCOR ≥ 1.9 V
−
−1.5
−
mA
VASCOR ≥ 1.9 V
−
50
−
µA
amplitude of horizontal
parabola (peak-to-peak value)
register HFOCUS = 0
−
0.06
−
V
register HFOCUS = 31
−
3.2
−
V
tprecor
pre-correction of phase
1.9 µs < tfb < 5.5 µs
−
350
−
ns
tW(hfb)(min)
minimum horizontal flyback
pulse width
typical tprecor = 350 ns
1.9
−
−
µs
tW(hfb)(max)
maximum horizontal flyback
pulse width
typical tprecor = 350 ns
−
−
5.5
µs
tW(hfb)(TV)(max)
maximum horizontal flyback
pulse width (TV)
typical td = 300 ns
−
−
12.5
µs
VVFOCUS(p-p)
amplitude of vertical parabola
(peak-to-peak value)
register VFOCUS = 0;
note 8
−
0.02
−
V
register VFOCUS = 07;
note 8
−
0.8
−
V
Io(sink)(ASCOR)(max) maximum output sink current
Focus section: pin FOCUS; TDA4854 only
VHFOCUS(p-p)
Vo(FOCUS)(max)
maximum output voltage
IFOCUS = 0
5.7
6
6.3
V
Vo(FOCUS)(min)
minimum output voltage
IFOCUS = 0
1.7
2
2.3
V
Io(FOCUS)(max)
maximum output current
±1.5
−
−
mA
CL(FOCUS)(max)
maximum capacitive load
−
−
20
pF
B+ control section; see Figs 23 and 24
TRANSCONDUCTANCE AMPLIFIER: PINS BIN AND BOP
Vi(BIN)
input voltage pin 5
0
−
5.25
V
Ii(BIN)(max)
maximum input current pin 5
−
−
±1
µA
Vref(int)
reference voltage at internal
non-inverting input of OTA
2.37
2.5
2.58
V
Vo(BOP)(min)
minimum output voltage pin 3
−
−
0.5
V
Vo(BOP)(max)
maximum output voltage pin 3
5.0
5.3
5.6
V
Io(BOP)(max)
maximum output current pin 3
−
±500
−
µA
gm(OTA)
transconductance of OTA
note 11
30
50
70
mS
Gv(ol)
open-loop voltage gain
note 12
−
86
−
dB
1999 Jul 13
IBOP < 1 mA
24
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
CBOP(min)
PARAMETER
TDA4853; TDA4854
CONDITIONS
minimum value of capacitor at
pin 3
MIN.
TYP.
MAX.
UNIT
10
−
−
nF
VOLTAGE COMPARATOR: PIN BSENS
Vi(BSENS)
voltage range of positive
comparator input
0
−
5
V
Vi(BOP)
voltage range of negative
comparator input
0
−
5
V
IL(BSENS)(max)
maximum leakage current
discharge disabled
−
−
−2
µA
OPEN-COLLECTOR OUTPUT STAGE: PIN BDRV
Io(BDRV)(max)
maximum output current
20
−
−
mA
ILO(BDRV)
output leakage current
VBDRV = 16 V
−
−
3
µA
Vsat(BDRV)
saturation voltage
IBDRV < 20 mA
−
−
300
mV
toff(BDRV)(min)
minimum off-time
td(BDRV-HDRV)
delay between BDRV pulse
and HDRV pulse
−
250
−
ns
measured at
VHDRV = VBDRV = 3 V
−
500
−
ns
BSENS DISCHARGE CIRCUIT: PIN BSENS
VSTOP(BSENS)
discharge stop level
capacitive load;
IBSENS = 0.5 mA
0.85
1.0
1.15
V
Idch(BSENS)
discharge current
VBSENS > 2.5 V
4.5
6.0
7.5
mA
Vth(BSENS)(restart)
threshold voltage for restart
fault condition
1.2
1.3
1.4
V
CBSENS(min)
minimum value of capacitor at
BSENS (pin 4)
2
−
−
nF
Internal reference, supply voltage, soft start and protection
VCC(stab)
external supply voltage for
complete stabilization of all
internal references
9.2
−
16
V
ICC
supply current
−
70
−
mA
ICC(stb)
standby supply current
STDBY = 1; VPLL2 < 1 V;
3.5 V < VCC < 16 V
−
9
−
mA
PSRR
power supply rejection ratio of
internal supply voltage
f = 1 kHz
50
−
−
dB
VCC(blank)
supply voltage level for
activation of continuous
blanking
VCC decreasing from 12 V 8.2
8.6
9.0
V
VCC(blank)(min)
minimum supply voltage level
for function of continuous
blanking
VCC decreasing from 12 V 2.5
3.5
4.0
V
Von(VCC)
supply voltage level for
activation of HDRV, BDRV,
VOUT1, VOUT2 and
HUNLOCK
VCC increasing from below 7.9
typical 8 V
8.3
8.7
V
1999 Jul 13
25
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
SYMBOL
Voff(VCC)
PARAMETER
supply voltage level for
deactivation of BDRV, VOUT1,
VOUT2 and HUNLOCK; also
sets register SOFTST
TDA4853; TDA4854
CONDITIONS
VCC decreasing from
above typical 8.3 V
MIN.
TYP.
MAX.
UNIT
7.7
8.1
8.5
V
THRESHOLDS DERIVED FROM HPLL2 VOLTAGE
VHPLL2(blank)(ul)
upper limit voltage for
continuous blanking
−
4.7
−
V
VHPLL2(bduty)(ul)
upper limit voltage for variation
of BDRV duty cycle
−
3.4
−
V
VHPLL2(bduty)(ll)
lower limit voltage for variation
of BDRV duty cycle
−
2.8
−
V
VHPLL2(hduty)(ul)
upper limit voltage for variation
of HDRV duty cycle
−
2.8
−
V
VHPLL2(hduty)(ll)
lower limit voltage for variation
of HDRV duty cycle
−
1.7
−
V
VHPLL2(stby)(ll)
lower limit voltage for VOUT1
and VOUT2 to be active via
I2C-bus soft start
−
1.1
−
V
VHPLL2(stby)(ul)
upper limit voltage for standby
voltage
−
1
−
V
VHPLL2(stby)(ll)
lower limit voltage for VOUT1
and VOUT2 to be active via
external DC current
−
0
−
V
Notes
1. For duration of vertical blanking pulse see subheading ‘Vertical oscillator [oscillator frequency in application without
adjustment of free-running frequency ffr(V)]’.
2. Continuous blanking at CLBL (pin 16) will be activated, if one of the following conditions is true:
a) No horizontal flyback pulses at HFLB (pin 1) within a line
b) X-ray protection is triggered
c) Voltage at HPLL2 (pin 30) is low during soft start
d) Supply voltage at VCC (pin 10) is low
e) PLL1 unlocked while frequency-locked loop is in search mode.
3. Oscillator frequency is fmin when no sync input signal is present (continuous blanking at pins 16 and 17).
4. Loading of HPLL1 (pin 26) is not allowed.
5. Voltage at HPLL1 (pin 26) is fed to HBUF (pin 27) via a buffer. Disturbances caused by horizontal sync are removed
by an internal sample-and-hold circuit.
6. All vertical and EW adjustments in accordance with note 8, but VSIZE = 80% (register VSIZE = 63 and control
bit VOVSCN = 0).
7. Value of resistor at VREF (pin 23) may not be changed.
8. All vertical and EW adjustments are specified at nominal vertical settings; unless otherwise specified, which means:
a) VSIZE = 100% (register VSIZE = 127 and control bit VOVSCN = 0)
b) VSMOD = 0 (no EHT compensation)
1999 Jul 13
26
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
c) VPOS centred (register VPOS = X and control
bit VPC = 1)
TDA4853; TDA4854
10. If fH tracking is enabled, the amplitude of the complete
EWDRV output signal (horizontal pincushion + corner
correction + DC shift + trapezium) will be changed
proportional to IHREF. The EWDRV low level of 1.2 V
remains fixed.
d) VLIN = 0 (register VLIN = X and control
bit VSC = 1)
e) VLINBAL = 0 (register VLINBAL = X and control
bit VLC = 1)
11. First pole of transconductance amplifier is 5 MHz
without external capacitor (will become the second
pole, if the OTA operates as an integrator).
f) FHMULT = 0
g) HPARAL = 0 (register HPARAL = X and control
bit HPC = 1)
V BOP
12. Open-loop gain is -------------- at f = 0 with no resistive load
V BIN
h) HPINBAL = 0 (register HPINBAL = X and control
bit HBC = 1)
and CBOP = 10 nF [from BOP (pin 3) to GND].
i) Vertical oscillator synchronized
j) HSIZE = 255.
9. The output signal at EWDRV (pin 11) may consist of
horizontal pincushion + corner correction + DC shift +
trapezium correction. If the control bit VOVSCN is set,
and the VPOS adjustment is set to an extreme value,
the tip of the parabola may be clipped at the upper limit
of the EWDRV output voltage range. The waveform of
corner correction will clip if the vertical sawtooth
adjustment exceeds 110% of the nominal setting.
Vertical and EW adjustments
MBG590
handbook, halfpage
IVOUT1
handbook, halfpage
IVOUT2
IVOUT2
MBG592
IVOUT1
∆l2
∆l1(1)
∆l1(1) ∆l2
t
t
(1) ∆I1 is the maximum amplitude setting at register VSIZE = 127,
control bit VOVSCN = 0, control bit VPC = 1,
control bit VSC = 1 and control bit VLC = 1.
∆I 2
VSIZE = -------- × 100%
∆I 1
(1) ∆I1 is the maximum amplitude setting at register VSIZE = 127
and control bit VPC = 1.
∆I 2
VSMOD = -------- × 100%
∆I 1
∆I 2 – ∆I 1
VPOS = ---------------------- × 100%
2 × ∆I 1
Fig.5 Adjustment of vertical size.
1999 Jul 13
Fig.6 Adjustment of vertical position.
27
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
IVOUT1
IVOUT1
∆l2/∆t
IVOUT2
MGM068
handbook, halfpage
MBG594
handbook, halfpage
TDA4853; TDA4854
IVOUT2
∆l1(1)/∆t
∆I2
∆I1(1)
t
t
(1) ∆I1 is the maximum amplitude setting at register VSIZE = 127
and VLIN = 0%.
(1) ∆I1 is the maximum amplitude setting at register VSIZE = 127,
register VOVSCN = 0, control bit VPC = 1, control bit VLIN = 1
and control bit VLINBAL = 0.
∆I 1 – ∆I 2
VLIN = ---------------------- × 100%
∆I 1
Fig.7
∆I 1 – ∆I 2
VLINBAL = ---------------------- × 100%
2 × ∆I 1
Adjustment of vertical linearity (vertical
S-correction).
handbook, halfpage
Fig.8 Adjustment of vertical linearity balance.
MGM070
handbook, halfpage
MGM069
VEWDRV
VEWDRV
VHCOR(EWDRV)
VHPIN(EWDRV)
t
Fig.9
t
Adjustment of parabola amplitude at
pin EWDRV.
1999 Jul 13
Fig.10 Influence of corner correction at
pin EWDRV.
28
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
MGM071
handbook, halfpage
TDA4853; TDA4854
MGM072
handbook, halfpage
VEWDRV
VEWDRV
VHTRAP(EWDRV)
VHSIZE(EWDRV)
+
VHEHT(EWDRV)
t
t
Fig.12 Influence of HSIZE and EHT compensation
at pin EWDRV.
Fig.11 Influence of trapezium at pin EWDRV.
MGM073
handbook, halfpage
handbook, halfpage
VASCOR
Vc(ASCOR)
MGM074
VASCOR
Vc(ASCOR)
VHPARAL(ASCOR)
VHPINBAL(ASCOR)
t
t
Fig.13 Adjustment of parallelogram at pin ASCOR.
1999 Jul 13
Fig.14 Adjustment of pin balance at pin ASCOR.
29
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
Pulse diagrams
handbook, full pagewidth
4.0 V automatic trigger level
3.8 V synchronized trigger level
vertical oscillator sawtooth
at VCAP (pin 24)
1.4 V
vertical sync pulse
inhibited
internal trigger
inhibit window
(typical 4 ms)
vertical blanking pulse
at CLBL (pin 16)
vertical blanking pulse
at HUNLOCK (pin 17)
IVOUT1
differential output currents
VOUT1 (pin 13) and
VOUT2 (pin 12)
IVOUT2
7.0 V maximum
EW drive waveform
at EWDRV (pin 11)
DC shift 3.6 V maximum
low-level 1.2 V fixed
MGM075
Fig.15 Pulse diagram for vertical part.
1999 Jul 13
30
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
handbook, full pagewidth
horizontal oscillator sawtooth
at HCAP (pin 29)
horizontal sync pulse
PLL1 control current
at HPLL1 (pin 26)
+
-
video clamping pulse
at CLBL (pin 16)
triggered on trailing edge
of horizontal sync
vertical blanking level
line flyback pulse
at HFLB (pin 1)
PLL2 control current
at HPLL2 (pin 30)
line drive pulse
at HDRV (pin 8)
+
–
PLL2
control range
45 to 52% of line period
horizontal focus parabola
at FOCUS (pin 32)
tprecor
Fig.16 Pulse diagram for horizontal part.
1999 Jul 13
31
MGM076
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
handbook, full pagewidth
TDA4853; TDA4854
MGM077
relative tHDRV(OFF)/tH
(%)
52
45
15
30
110
130 f (kHz)
H
Fig.17 Relative tOFF time of HDRV as a function of horizontal frequency.
handbook, fullcomposite
pagewidth sync (TTL)
at HSYNC (pin 15)
internal integration of
composite sync
internal vertical
trigger pulse
PLL1 control voltage
at HPLL1 (pin 26)
clamping and blanking
pulses at CLBL (pin 16)
MGC947
a. Reduced influence of vertical sync on horizontal phase.
handbook, full pagewidth
composite sync (TTL)
at HSYNC (pin 15)
clamping and blanking
pulses at CLBL (pin 16)
MBG596
b. Generation of video clamping pulses during vertical sync with serration pulses.
Fig.18 Pulse diagrams for composite sync applications.
1999 Jul 13
32
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
I2C-BUS PROTOCOL
I2C-bus data format
S(1)
SLAVE ADDRESS(2)
A(3)
SUBADDRESS(4)
A(3)
DATA(5)
A(3)
P(6)
Notes
1. S = START condition.
2. SLAVE ADDRESS (MAD) = 1000 1100.
3. A = acknowledge, generated by the slave. No acknowledge, if the supply voltage is below 8.3 V for start-up and 8.1 V
for shut-down procedure.
4. SUBADDRESS (SAD).
5. DATA, if more than 1 byte of DATA is transmitted, then no auto-increment of the significant subaddress is performed.
6. P = STOP condition.
It should be noted that clock pulses according to the 400 kHz specification are accepted for 3.3 and 5 V applications
(reference level = 1.8 V). Default register values after power-up are random. All registers have to be preset via software
before the soft start is enabled.
Important: If the register contents are changed during the vertical scan, this might result in a visible interference on the
screen. The cause for this interference is the abrupt change in picture geometry which takes effect at random locations
within the visible picture.
To avoid this kind of interference, the adjustment of the critical geometry parameters HSIZE, HPOS, VSIZE and VPOS
should be synchronized with the vertical flyback. This should be done in such a way that the adjustment change takes
effect during the vertical blanking time (see Fig.19).
For very slow I2C-bus interfaces, it might be necessary to delay the transmission of the last byte (or only the last bit) of
an I2C-bus message until the start of the vertical sync or vertical blanking.
vertical
handbook, full pagewidth
sync pulse
vertical
blanking pulse
SDA
parameter change takes effect
MGM088
Fig.19 Timing of the I2C-bus transmission for interference-free adjustment.
1999 Jul 13
33
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
Table 4
TDA4853; TDA4854
List of I2C-bus controlled switches; notes 1 and 2
CONTROL
BIT
BLKDIS
REGISTER ASSIGNMENT
SAD
(HEX) D7 D6 D5 D4 D3 D2 D1 D0
FUNCTION
0: vertical, protection and horizontal unlock blanking
available on pins CLBL and HUNLOCK
01
X
#
#
#
#
#
#
D0
01
X
#
#
#
#
#
D1 #
01
X
#
#
#
#
D2 #
01
X
#
#
#
D3 #
01
X
#
#
D4 #
01
X
#
D5 #
01
X
D6 #
0B
#
#
0B
#
0B
1: only vertical and protection blanking available on
pins CLBL and HUNLOCK
HBC
0: HPINBAL (parabola) waveform enabled
1: HPINBAL (parabola) waveform disabled
HPC
0: HPARAL (sawtooth) waveform enabled
#
1: HPARAL (sawtooth) waveform disabled
AGCDIS
0: AGC in vertical oscillator active
#
#
#
#
#
#
#
#
#
#
#
#
#
#
#
#
#
#
X
D0
#
#
#
#
D2 X
#
#
#
#
D3 #
0B
#
#
#
D4 #
0B
#
#
D5 #
0B
#
D6 #
0B
D7 #
0D
X
0D
X
1: AGC in vertical oscillator inhibited
VSC
0: VLIN and HCOR adjustments enabled
1: VLIN and HCOR adjustments forced to centre value
MOD
0: horizontal and vertical moire cancellation enabled
1: horizontal and vertical moire cancellation disabled
TVMOD
0: TV mode at fmin not activated
1: TV mode at fmin activated
FHMULT
0: EW output independent of horizontal frequency
1: EW output tracks with horizontal frequency
VOVSCN
0: vertical size 100%
#
1: vertical size 116.8% for VGA350
CLAMP
0: trailing edge for horizontal clamp
X
#
#
X
#
#
#
X
#
#
#
#
X
#
#
#
#
#
X
#
X
X
X
X
X
#
D0
X
X
X
X
X
D1 #
1: leading edge for horizontal clamp
VBLK
0: vertical blanking = 260 µs
1: vertical blanking = 340 µs
VLC
0: VLINBAL adjustment enabled
1: VLINBAL adjustment forced to centre value
VPC
0: VPOS and HTRAP adjustments enabled
1: VPOS and HTRAP adjustments forced to centre value
ACD
0: ASCOR disconnected from PLL2
1: ASCOR internally connected with PLL2
STDBY(3)
0: internal power supply enabled
1: internal power supply disabled
SOFTST(3)
0: soft start not released (pin HPLL2 pulled to ground)
1: soft start is released (power-up via pin HPLL2)
Notes
1. X = don’t care.
2. # = this bit is occupied by another function. If the register is addressed, the bit values for both functions must be
transferred.
3. Bits STDBY and SOFTST can be reset by internal protection circuit.
1999 Jul 13
34
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REGISTER ASSIGNMENT
SAD
(HEX) D7 D6 D5 D4 D3 D2 D1 D0
FUNCTION
NAME
BITS
Horizontal size
HSIZE
8
00
D7 D6 D5 D4 D3 D2 D1 D0
Vertical position
VPOS
7
02
D7 D6 D5 D4 D3 D2 D1
Vertical linearity
balance
VLINBAL
4
03
X
Moire cancellation
via vertical
position
VMOIRE
3
03
#
#
HPIN
6
04
X
X
HMOIRE
5
05
X
X
HPOS
8
06
D7 D6 D5 D4 D3 D2 D1 D0
Vertical linearity
VLIN
4
07
D7 D6 D5 D4
EW pin balance
HPINBAL
4
07
Horizontal
pincushion
Moire cancellation
via horizontal
position
35
Horizontal
position
7
08
HCOR
5
09
Horizontal
trapezium
correction
HTRAP
4
0C
Horizontal
parallelogram
HPARAL
4
0C
#
#
#
X
#
#
X
#
VSMOD
±2.5% of 100%
vertical size
VSIZE, VOVSCN,
VPOS and
VSMOD
MOD
0 to 0.08% of
vertical amplitude
−
0 to 1.44 V
VSIZE, VOVSCN,
VPOS, HSIZE and
HSMOD
0 to 0.05% of
horizontal period
−
#
#
#
#
D3 D2 D1 D0
X
D4 D3 D2 D1 D0
D7 D6 D5 D4
#
±11.5%
VLC
D2 D1 D0
D7 D6 D5 D4 D3 D2 D1
X
VPC
#
D4 D3 D2 D1 D0
#
#
#
#
#
HSMOD
X
D5 D4 D3 D2 D1 D0
X
0.1 to 3.6 V
#
D3 D2 D1 D0
−
MOD
−
VSC
HBC and
ACD
−
±13% of horizontal −
period
−2 to −46%
VSIZE, VOVSCN,
VPOS and
VSMOD
±1% of
horizontal period
VSIZE, VOVSCN
and VPOS
60 to 100%
VSMOD
VSC
+6 to −46% of
parabola
amplitude
VSIZE, VOVSCN,
VPOS, HSIZE and
HSMOD
VPC
±0.33 V
VSIZE, VOVSCN,
VPOS, HSIZE and
HSMOD
±1% of horizontal
period
VSIZE, VOVSCN
and VPOS
HPC and
ACD
Product specification
VSIZE
Horizontal corner
correction
#
#
#
−
FUNCTION
TRACKS WITH
RANGE
TDA4853; TDA4854
Vertical size
#
D6 D5 D4 D3
CONTROL
BIT
Philips Semiconductors
List of I2C-bus controlled functions and those accessible by pins; notes 1 and 2
I2C-bus autosync deflection controllers for
PC/TV monitors
1999 Jul 13
Table 5
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BITS
Vertical focus
VFOCUS
3
0A
Horizontal focus
HFOCUS
5
0A
CONTROL
BIT
FUNCTION
TRACKS WITH
RANGE
TDA4854
D7 D6 D5
#
#
#
#
#
#
#
#
D4 D3 D2 D1 D0
−
0 to 25%
VSIZE, VOVSCN
and VPOS
−
0 to 100%
−
Notes
1. X = don’t care.
2. # = this bit is occupied by another function. If the register is addressed, the bit values for both functions must be transferred.
Philips Semiconductors
REGISTER ASSIGNMENT
SAD
(HEX) D7 D6 D5 D4 D3 D2 D1 D0
NAME
36
I2C-bus autosync deflection controllers for
PC/TV monitors
1999 Jul 13
FUNCTION
Product specification
TDA4853; TDA4854
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
Start-up procedure
VCC < 8.3 V:
START
• As long as the supply voltage is too low for correct
operation, the IC will give no acknowledge due to
internal Power-on reset (POR)
L1
Power-down mode (XXXX XXXX)
• Supply current is 9 mA or less.
no acknowledge is given by IC
all register contents are random
VCC > 8.3 V:
VCC > 8.3 V
• The internal POR has ended and the IC is in standby
mode
L2
Standby mode (XXXX XX01)
STDBY = 1
SOFTST = 0
all other register contents are random
S
8CH
A
0DH
A
00H
• Control bits STDBY and SOFTST are reset to their start
values
• All other register contents are random
A P
• Pin HUNLOCK is at HIGH-level.
Setting control bit STDBY = 0:
Protection mode (XXXX XX00)
• Enables internal power supply
STDBY = 0
SOFTST = 0
all other register contents are random
S
8CH
A
SAD
A
DATA
• Supply current increases from 9 to 70 mA
• When VCC < 8.6 V register SOFTST cannot be set by
the I2C-bus
A P
• Output stages are disabled, except the vertical output
• Pin HUNLOCK is at HIGH-level.
Protection mode (XXXX XX00)
Setting all registers to defined values:
STDBY = 0
SOFTST = 0
registers are pre-set
no
• Due to the hardware configuration of the IC
(no auto-increment) any register setting needs a
complete 3-byte I2C-bus data transfer as follows:
START - IC address - subaddress - data - STOP.
all registers defined?
Setting control bit SOFTST = 1:
yes
S
8CH
A
0DH
A
02H
• Before starting the soft-start sequence a delay of
minimum 80 ms is necessary to obtain correct function
of the horizontal drive
L3
A P
Soft-start sequence (XXXX XX10)
• HDRV duty cycle increases
STDBY = 0
SOFTST = 1
• BDRV duty cycle increases
• PLL1 and PLL2 are enabled.
Operating mode (XXXX XX10)
IC in full operation:
STDBY = 0
SOFTST = 1
no
change/refresh of data?
SOFTST = 0?
yes
S
8CH
A
SAD
A
• Pin HUNLOCK is at LOW-level when PLL1 is locked
• Any change of the register content will result in
immediate change of the output behaviour
no
• Setting control bit SOFTST = 0 is the only way (except
power-down via pin VCC) to leave the operating mode.
yes
DATA
A P
L4 (1)
Soft-down sequence:
MGM078
• See L4 of Fig.21 for starting the soft-down sequence.
(1) See Fig.21.
Fig.20 I2C-bus flow for start-up.
1999 Jul 13
37
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
Protection and standby mode
Soft-down sequence:
L4
S
8CH
A
0DH
• Start the sequence by setting control bit SOFTST = 0
A
00H
• BDRV duty cycle decreases
A P
• HDRV duty cycle decreases.
Protection mode:
Soft-down sequence (XXXX XX00)
• Pins HDRV and BDRV are floating
STDBY = 0
SOFTST = 0
• Continuous blanking at pin CLBL is active
• Pin HUNLOCK is floating
Protection mode (XXXX XX00)
• PLL1 and PLL2 are disabled
STDBY = 0
SOFTST = 0
registers are set
• Register contents are kept in internal memory.
Protection mode can be left by 3 ways:
no
STDBY = 1?
1. Entering standby mode by setting control
bit SOFTST = 0 and control bit STDBY = 1
no
SOFTST = 1?
2. Starting the soft-start sequence by setting control
bit SOFTST = 1 (bit STDBY = don’t care);
see L3 of Fig.20 for continuation
yes
yes
L3 (1)
3. Decreasing the supply voltage below 8.1 V.
S
8CH
A
0DH
A
01H
A P
Standby mode:
• Set control bit STDBY = 1
• Driver outputs are floating (same as protection mode)
Standby mode (XXXX XX01)
STDBY = 1
SOFTST = 0
all other register contents are random
L2 (1)
• Supply current is 9 mA
• Only the I2C-bus and protection circuits are operative
• Contents of all registers except the value of bit STDBY
and bit SOFTST are lost
MBK382
• See L2 of Fig.20 for continuation.
(1) See Fig.20.
Fig.21 I2C-bus flow for protection and standby
mode.
1999 Jul 13
38
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
handbook, full pagewidth
TDA4853; TDA4854
(ANY Mode)
VCC < 8.1 V
Power-Down Mode
VCC
no acknowledge is given by IC
all register contents are random
8.6 V
a soft-down sequency followed by a
soft start sequence is generated
internally.
8.1 V
VCC
8.6 V
8.1 V
L1 (1)
IC enters standby mode.
MGM079
(1) See Fig.20.
Fig.22 I2C-bus flow for any mode.
Power-down mode
Power dip of VCC < 8.6 V:
• The soft-down sequence is started first.
• Then the soft-start sequence is generated internally.
Power dip of VCC < 8.1 V or VCC shut-down:
• This function is independent from the operating mode, so it works under any condition.
• All driver outputs are immediately disabled
• IC enters standby mode.
1999 Jul 13
39
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
APPLICATION INFORMATION
VCC
handbook, full pagewidth
Vi
2 VHDRV
VHPLL2
R6(1)
6
SOFT START
S
3 VBDRV
D2
Q
OTA
2.5 V
L
TR1
R
Q
INVERTING
BUFFER
HORIZONTAL
OUTPUT
STAGE
DISCHARGE
1 horizontal
flyback pulse
D1
5
3
VBIN
VBOP
4
R5
4 VBSENS
R1
R4
C4
C1
R2
C2
R3
MGM080
CBOP
>10 nF
EWDRV
For f < 50 kHz and C2 < 47 nF calculation formulas and behaviour of the OTA are the same as for an OP. An exception is the limited output current at
BOP (pin 3). See Chapter “Characteristics”, Row Head “B+ control section; see Figs 23 and 24”.
(1) The recommended value for R6 is 1 kΩ.
a. Feedback mode application.
handbook, full pagewidth
1 horizontal
flyback pulse
2 VHDRV
ton
3 VBDRV
td(BDRV)
toff(min)
VBSENS = VBOP
VRESTART(BSENS)
4 VBSENS
VSTOP(BSENS)
MBG600
b. Waveforms for normal operation.
c. Waveforms for fault condition.
Fig.23 Application and timing for feedback mode.
1999 Jul 13
40
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
VCC
2 VHDRV
VHPLL2
horizontal
flyback pulse
1
R4(1)
6
INVERTING
BUFFER
SOFT START
S
Q
R
Q
OTA
2.5 V
3 VBDRV
HORIZONTAL
OUTPUT
STAGE
EHT
transformer
D2
5 IMOSFET
DISCHARGE
5
EHT adjustment
3
R1
TR1
4
VBOP
R2
VBIN
R3
D1
4 VBSENS
C1
CBSENS
MGM081
TR2
power-down
>2 nF
CBOP > 10 nF
(1) The recommended value for R4 is 1 kΩ.
a. Forward mode application.
handbook,
pagewidth
1 full
horizontal
flyback pulse
2 VHDRV
ton
3 VBDRV
toff
td(BDRV)
VBOP
(discharge time of CBSENS)
VBOP
4 VBSENS
VRESTART(BSENS)
VSTOP(BSENS)
5 IMOSFET
MBG602
b. Waveforms for normal operation.
c. Waveforms for fault condition.
Fig.24 Application and timing for feed forward mode.
1999 Jul 13
41
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
Start-up sequence and shut-down sequence
handbook, full pagewidth
MGM082
VCC
8.6 V continuous blanking off
PLL2 soft start/soft-down enabled(1)
8.3 V
3.5 V
data accepted from I2C-bus
video clamping pulse enabled if control bit STDBY = 0
continuous blanking (pin 16 and 17) activated
time
a. Start-up sequence.
MGM083
handbook, full pagewidth
VCC
8.6 V continuous blanking (pin 16 and 17) activated
PLL2 soft-down sequence is triggered(2)
8.1 V
no data accepted from I2C-bus
video clamping pulse disabled
3.5 V
continuous blanking disappears
time
b. Shut-down sequence.
(1) See Figs 20, 21, 22, 26 and 27.
(2) See Figs 26b and 27b.
Fig.25 Start-up sequence and shut-down sequence.
1999 Jul 13
42
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
PLL2 soft start sequence and PLL2 soft-down sequence
MGM084
handbook, full pagewidth
VHPLL2
as
es
4.7 V continuous blanking off
PLL2 enabled
frequency detector enabled
HDRV/HFLB protection enabled
BDRV duty cycle has reached nominal value
cy
cl
e
in
cr
e
3.4 V
BDRV duty cycle begins to increase
HDRV duty cycle has reached nominal value
du
ty
2.8 V
1.7 V
1V
HDRV duty cycle begins to increase
VOUT1 and VOUT2 enabled
time
a. PLL2 soft start sequence, via the I2C-bus, if VCC > 8.6 V.
MGM085
handbook, full pagewidth
VHPLL2
4.7 V continuous blanking (pin 16 and 17) activated
PLL2 disabled
frequency detector disabled
HDRV/HFLB protection disabled
3.4 V
BDRV duty cycle begins to decrease(1)
ty
du
e
cl
cy
2.8 V
BDRV floating
HDRV duty cycle begins to decrease(1)
de
e
cr
HDRV floating
es
as
1.7 V
1V
VOUT1 and VOUT2 floating
time
b. PLL2 soft-down sequence, via the I2C-bus, if VCC > 8.6 V.
(1) HDRV, BDRV, VOUT2 and VOUT1 are floating for VCC < 8.6 V.
Fig.26 PLL2 soft start sequence and PLL2 soft-down sequence via the I2C-bus.
1999 Jul 13
43
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
MHB108
handbook, full pagewidth
VHPLL2
ea
se
s
4.6 V continuous blanking off
PLL2 enabled
frequency detector enabled
HDRV/HFLB protection enabled
BDRV duty cycle has reached nominal value
cl
e
in
cr
3.3 V
BDRV duty cycle begins to increase
HDRV duty cycle has reached nominal value
du
ty
cy
3.0 V
1.7 V
HDRV duty cycle begins to increase
time
a. PLL2 soft start sequence by external DC current, if VCC > 8.6 V.
MHB109
handbook, full pagewidth
VHPLL2
4.6 V continuous blanking (pin 16 and 17) activated
PLL2 disabled
frequency detector disabled
HDRV/HFLB protection disabled
3.3 V
BDRV duty cycle begins to decrease(1)
du
ty
le
c
cy
3.0 V
BDRV floating
HDRV duty cycle begins to decrease(1)
de
ea
cr
HDRV floating
s
se
1.7 V
time
b. PLL2 soft-down sequence by external DC current, if VCC > 8.6 V.
(1) HDRV, BDRV, VOUT2 and VOUT1 are floating for VCC < 8.6 V.
Fig.27 PLL2 soft start sequence and PLL2 soft-down sequence by external DC current.
1999 Jul 13
44
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
X-ray latch triggered
handbook, full pagewidth
VXRAY
VHUNLOCK
BDRV duty cycle
floating
HDRV duty cycle
floating
VOUT1, VOUT2
floating
approximately 25 ms
MGM087
Fig.28 Activation of the soft-down sequence via pin XRAY.
Vertical linearity error
handbook, halfpage
I
VOUT
(µA)
(1)
MBG551
+415
I1(2)
I2(3)
0
I3(4)
−415
VVCAP
(1) IVOUT = IVOUT1 − IVOUT2.
(2) I1 = IVOUT at VVCAP = 1.9 V.
(3) I2 = IVOUT at VVCAP = 2.6 V.
(4) I3 = IVOUT at VVCAP = 3.3 V.
I1 – I3
Which means: I 0 = -------------2
I2 – I3
I1 – I2
Vertical linearity error = 1 – max  -------------- or --------------
 I0
I0 
Fig.29 Definition of vertical linearity error.
1999 Jul 13
45
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
Printed-circuit board layout
further connections to other components
or ground paths are not allowed
17
18
19
20
22
23
24
25
external components of
vertical section
26
27
28
29
30
31
32
external components of
horizontal section
21
handbook, full pagewidth
pin 25 should be the 'star point'
for all small signal components
external components of
horizontal section
no external ground tracks
connected here
47 nF
2.2 nF
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
TDA4853; TDA4854
470 pF
100 µF
12 V
B-drive line in parallel
to ground
only this path may be connected
to general ground of PCB
MGM086
SMD
For optimum performance of the TDA4853; TDA4854 the ground paths must be routed as shown.
Only one connection to other grounds on the PCB is allowed.
Note: The tracks for HDRV and BDRV should be kept separate.
Fig.30 Hints for printed-circuit board (PCB) layout.
1999 Jul 13
46
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
INTERNAL PIN CONFIGURATION
PIN
1
SYMBOL
INTERNAL CIRCUIT
HFLB
1.5 kΩ
1
7x
MBG561
2
XRAY
5 kΩ
2
6.25 V
MBG562
3
BOP
5.3 V
3
MBG563
4
BSENS
4
MBG564
1999 Jul 13
47
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
5
SYMBOL
TDA4853; TDA4854
INTERNAL CIRCUIT
BIN
5
MBG565
6
BDRV
6
MBG566
7
PGND
8
HDRV
power ground, connected to substrate
8
MGM089
9
XSEL
4 kΩ
9
MBK381
10
VCC
10
MGM090
11
EWDRV
108 Ω
11
108 Ω
MBG570
1999 Jul 13
48
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
12
13
14
SYMBOL
TDA4853; TDA4854
INTERNAL CIRCUIT
VOUT2
12
MBG571
13
MBG572
VOUT1
VSYNC
100 Ω
1.4 V
14
2 kΩ
7.3 V
MBG573
15
HSYNC
1.28 V
85 Ω
1.4 V
15
7.3 V
MBG574
16
CLBL
16
MBG575
1999 Jul 13
49
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
17
SYMBOL
TDA4853; TDA4854
INTERNAL CIRCUIT
HUNLOCK
17
MGM091
18
SCL
18
MGM092
19
SDA
19
MGM093
20
ASCOR
480 Ω
20
MGM094
21
VSMOD
250 Ω
21
5V
MGM095
1999 Jul 13
50
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
22
SYMBOL
TDA4853; TDA4854
INTERNAL CIRCUIT
VAGC
22
MBG581
23
VREF
23
3V
MBG582
24
VCAP
24
MBG583
25
SGND
26
HPLL1
signal ground
26
4.3 V
MGM096
27
HBUF
27
5V
MGM097
1999 Jul 13
51
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
SYMBOL
28
HREF
29
HCAP
TDA4853; TDA4854
INTERNAL CIRCUIT
76 Ω
2.525 V
28
7.7 V
29
MBG585
30
HPLL2
7.7 V
30
HFLB
6.25 V
MGM098
31
HSMOD
250 Ω
31
5V
MGM099
1999 Jul 13
52
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
PIN
SYMBOL
TDA4853; TDA4854
INTERNAL CIRCUIT
FOCUS(1)
32
120 Ω
32
200 Ω
120 Ω
MGM100
Note
1. This pin is internally connected for TDA4853.
Electrostatic discharge (ESD) protection
pin
pin
7.3 V
MBG559
7.3 V
MBG560
Fig.31 ESD protection for pins 4, 11 to 13,
16 and 17.
1999 Jul 13
Fig.32 ESD protection for pins 2, 3, 5, 18 to 24
and 26 to 32.
53
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
PACKAGE OUTLINE
SDIP32: plastic shrink dual in-line package; 32 leads (400 mil)
SOT232-1
ME
seating plane
D
A2 A
A1
L
c
e
Z
(e 1)
w M
b1
MH
b
17
32
pin 1 index
E
1
16
0
5
10 mm
scale
DIMENSIONS (mm are the original dimensions)
UNIT
A
max.
A1
min.
A2
max.
b
b1
c
D (1)
E (1)
e
e1
L
ME
MH
w
Z (1)
max.
mm
4.7
0.51
3.8
1.3
0.8
0.53
0.40
0.32
0.23
29.4
28.5
9.1
8.7
1.778
10.16
3.2
2.8
10.7
10.2
12.2
10.5
0.18
1.6
Note
1. Plastic or metal protrusions of 0.25 mm maximum per side are not included.
OUTLINE
VERSION
REFERENCES
IEC
JEDEC
EIAJ
ISSUE DATE
92-11-17
95-02-04
SOT232-1
1999 Jul 13
EUROPEAN
PROJECTION
54
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
The total contact time of successive solder waves must not
exceed 5 seconds.
SOLDERING
Introduction to soldering through-hole mount
packages
The device may be mounted up to the seating plane, but
the temperature of the plastic body must not exceed the
specified maximum storage temperature (Tstg(max)). If the
printed-circuit board has been pre-heated, forced cooling
may be necessary immediately after soldering to keep the
temperature within the permissible limit.
This text gives a brief insight to wave, dip and manual
soldering. A more in-depth account of soldering ICs can be
found in our “Data Handbook IC26; Integrated Circuit
Packages” (document order number 9398 652 90011).
Wave soldering is the preferred method for mounting of
through-hole mount IC packages on a printed-circuit
board.
Manual soldering
Apply the soldering iron (24 V or less) to the lead(s) of the
package, either below the seating plane or not more than
2 mm above it. If the temperature of the soldering iron bit
is less than 300 °C it may remain in contact for up to
10 seconds. If the bit temperature is between
300 and 400 °C, contact may be up to 5 seconds.
Soldering by dipping or by solder wave
The maximum permissible temperature of the solder is
260 °C; solder at this temperature must not be in contact
with the joints for more than 5 seconds.
Suitability of through-hole mount IC packages for dipping and wave soldering methods
SOLDERING METHOD
PACKAGE
DIPPING
DBS, DIP, HDIP, SDIP, SIL
WAVE
suitable(1)
suitable
Note
1. For SDIP packages, the longitudinal axis must be parallel to the transport direction of the printed-circuit board.
1999 Jul 13
55
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
TDA4853; TDA4854
DEFINITIONS
Data sheet status
Objective specification
Preliminary specification
Product specification
This data sheet contains target or goal specifications for product development.
This data sheet contains preliminary data; supplementary data may be published later.
This data sheet contains final product specifications.
Limiting values
Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or
more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation
of the device at these or at any other conditions above those given in the Characteristics sections of the specification
is not implied. Exposure to limiting values for extended periods may affect device reliability.
Application information
Where application information is given, it is advisory and does not form part of the specification.
LIFE SUPPORT APPLICATIONS
These products are not designed for use in life support appliances, devices, or systems where malfunction of these
products can reasonably be expected to result in personal injury. Philips customers using or selling these products for
use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such
improper use or sale.
PURCHASE OF PHILIPS I2C COMPONENTS
Purchase of Philips I2C components conveys a license under the Philips’ I2C patent to use the
components in the I2C system provided the system conforms to the I2C specification defined by
Philips. This specification can be ordered using the code 9398 393 40011.
1999 Jul 13
56
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
NOTES
1999 Jul 13
57
TDA4853; TDA4854
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
NOTES
1999 Jul 13
58
TDA4853; TDA4854
Philips Semiconductors
Product specification
I2C-bus autosync deflection controllers for
PC/TV monitors
NOTES
1999 Jul 13
59
TDA4853; TDA4854
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For all other countries apply to: Philips Semiconductors,
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Internet: http://www.semiconductors.philips.com
© Philips Electronics N.V. 1999
SCA 67
All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner.
The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed
without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license
under patent- or other industrial or intellectual property rights.
Printed in The Netherlands
545004/02/pp60
Date of release: 1999
Jul 13
Document order number:
9397 750 05275