ETC WT9051

WT9051
Data Sheet REV1.0
PIN DESCRIPTION
Pin No. Pin Name
Description
1
GND1
The main ground pin for the
2
vertical circuit and the I C
bus circuit.
2
VOSC
Connect the capacitor for
oscillation of vertical saw
wave.
Please connect near pin,
because series resistance
component distorts
Rising waveform of the
vertical saw waveform. Use
the capacitor of the small
temperature drift.
Internal Equivalent Circuit
Wave Form
GND1
1
VCC
25uA
250uA
10uA
5.7V
10KΩ
2KΩ
1KΩ
2.7V
fv
2
5KΩ
1.25KΩ
GND1
GND2
3
VAGC
Connect the capacitor for
AGC of vertical saw
Amplitude of vertical saw
wave is held constant by the
AGC circuit.
DC Voltage=3~4V
Vcc
5KΩ
1.25KΩ
1KΩ
5KΩ
3
5KΩ
GND2
5KΩ
GND1
Weltrend Semiconductor, Inc.
Page 3
5KΩ
WT9051
Data Sheet REV1.0
4
VSAWO
The vertical
tical linearity S/C
compensation are added to
the vertical saw wave form
Vcc
2.5KΩ
5KΩ
Refers the following
picture image of
correction
5KΩ
4
5KΩ
3Vp-p
2.5KΩ
5KΩ
2.5KΩ
GND1
80KΩ
fv
GND2
5
EWO
Outputs the compensation Vcc
signal of the trapezoid, the
side pin, the side pin corner
and the horizontal size.
5
1KΩ
5KΩ
Refers the following
picture image of
correction
5KΩ
5KΩ
333Ω
5KΩ
GND2
6
VEI
GND1
Input the High voltage of the Vcc
25uA
EHT. For, it cancel a transient 370uA
response
5KΩ
5KΩ
of the deflecting voltage. If
this pin isn’t used, connect
5KΩ
10uF capacitor to GND.
DC voltage=4V
5KΩ
4V
10KΩ
10KΩ
6
GND2
7
HEI
10KΩ
Input the High voltage of the Vcc
EHT. For, it cancel a transient
5KΩ
response
of the deflecting voltage. If
this pin isn ’t used, connect
4.0V 10KΩ
10uFcapacitor to GND.
2.5KΩ
Weltrend Semiconductor, Inc.
Page 4
DC Voltage=4V
5KΩ
10KΩ
5KΩ
23.33KΩ
7
GND1
2.5Ω
2.5KΩ
WT9051
Data Sheet REV1.0
8
DFMIXO
Outputs the mixed signal of
horizontal and vertical
parabola wave for dynamic
focus signal.
Vcc
2.5KΩ
5KΩ
8
2.5KΩ
10KΩ
2.5KΩ
5KΩ
5KΩ
80KΩ
2.5KΩ
GND2
9
HPHASE-C Connect the capacitor 10 μF Vcc
AP
to GND
10KΩ
9
1.67KΩ
1KΩ
14KΩ
2.5KΩ
GND2
10
HDSA
Connect the capacitor for
oscillation of Horizontal
dynamic focus signal.
DC Voltage=3~4V
Vcc
5KΩ
5KΩ
10
5KΩ
5K
Ω
5KΩ
2.5KΩ
GND2
11
BAMPI
The input of the error
Vcc
amplifier for the high voltage
control.
50uA
5KΩ
100uA
2.5KΩ
5KΩ
11
5KΩ
5KΩ
Weltrend Semiconductor, Inc.
Page 5
5KΩ
DC Voltage
WT9051
Data Sheet REV1.0
12
BAMPO
Outputs the voltage to control
the PWM pulse width.
Vcc
DC Voltage
1KΩ
5KΩ
5KΩ
12
1KΩ
5KΩ
GND2
13
PSAW
Connect the capacitor and
the resistance for oscillation
of PWM.
Vcc
5kΩ
5KΩ
V12pin
1.7V
13
400Ω
1V
5KΩ
fH
300KΩ
GND2
14
PWMO
Outputs the PWM pulse
Vcc
25uA 25uA
3.33KΩ
30KΩ
Please connect the drive
20KΩ
30KΩ
transistor, because it doesn't
have an enough driving force.
14
0.7V
0V
5KΩ
fH
30KΩ
5KΩ
GND2
15
16
GND2
VCC
The main ground pin for the
horizontal circuit.
15
GND2
Input 12volts for the power
supply.
16
Vcc
Weltrend Semiconductor, Inc.
Page 6
DC voltage=12V
WT9051
Data Sheet REV1.0
17
HOUT
Outputs the horizontal derive Vcc
pulse
20K
20K
50K
17
7.5KΩ
0.7V
3KΩ
0V
GND2
fH
18
FBP
Input the fly back pulse
Vcc
50uA
100uA
5KΩ
5V
2.5KΩ
10KΩ
18
0V
5KΩ
10KΩ
fH
GND2
19
XRAY
The input pin for the X ray
protection.
Vcc
25uA
5KΩ
25uA
The bias voltage of the
outside
5KΩ
5KΩ
19
GND2
20
VREF
Outputs the internal reference Vcc 25uA 25uA
106uA
DC voltage=5V
voltage, and creates a
5KΩ
5KΩ
5KΩ
internal
Reference current by the
resistance. Please connect
10KΩ
10KΩ
the resistor and
Capacitor near this pin,
because noise component
38KΩ
input to this pin affects
20
Horizontal jitter. A current
10KΩ
12KΩ
control
function
is
not
GND2
provided, such that an
External circuit cannot use
the voltage output from this
pin.
Weltrend Semiconductor, Inc.
Page 7
WT9051
Data Sheet REV1.0
21
HFVO
Outputs the voltage tracking
to the horizontal frequency.
Please connect the resistor
and capacitor near this pin,
because noise component
input to this pin affects
horizontal jitter
Vcc 25uA
DC voltage tracking to
the horizontal frequency
25uA
10KΩ
10KΩ
15KΩ
5KΩ
15KΩ
25KΩ
25KΩ
5KΩ
4.8V
21
5KΩ
5KΩ
GND2
22
HFVR
Vcc
Creates the current for the
horizontal oscillator. Please
825Ω
connect this resistor near this
pin, because noise
component input to this pin
affects horizontal jitter.
25uA
Same voltage that pin21
25uA
10KΩ
10KΩ
15KΩ 15KΩ
22
5KΩ
5KΩ
GND2
23
HOSC
Please connect the capacitor
(390pF) for horizontal
oscillation.
Vcc
463uA
2.5KΩ
1.25KΩ
23
9.9V
4.9V
fH
1.25KΩ
GND2
24
HAFC
Creates the current for the
Vcc
horizontal oscillator. Please
connect this resistor near this
pin, because noise
component input to this pin
affects horizontal jitter.
Please connect the capacitor 24
(390pF) for horizontal
oscillation. Connect the filter
for the auto frequency control
of horizontal. Following is the
item that the filter affects
GND2
jitter. The time constant of the
filter The noise of the Vcc and
GND. Connect resistor and
capacitor near this pin.
Weltrend Semiconductor, Inc.
Page 8
2.5KΩ
1.67KΩ
3.5V
5KΩ
24KΩ
5KΩ
5KΩ
8KΩ
fH
WT9051
Data Sheet REV1.0
25
HLO
The lock detection output of
the horizontal oscillator
Vcc
10uA
5V
20KΩ
10uA
2.5KΩ
DC voltage
2.5KΩ
5KΩ
25
5KΩ
5V
Lock
5KΩ
0V
Unlock
GND2
26
HIN
The separate horizontal sync Vcc 50uA
50uA
signal input is a direct
5KΩ
5KΩ
connection.
5KΩ
5KΩ
5.0V
10KΩ
85Ω
26
0.0V
fH
5KΩ
5KΩ
5KΩ
separate sync
GND2
27
VIN
The separate Vertical sync
signal input is a direct Vcc
5V
connection.
4.7V
5KΩ
2.5V
5KΩ
0V
27
500Ω
fv
separate sync
5KΩ
GND2
28
BLKO
Outputs the following 3 items
2
by I C bus. The mixed signal Vcc
of the vertical blanking pulse
and the video clamp pulse.
The vertical blanking pulse
only. The video clamp pulse
28
only.
5KΩ
GND1
2.5KΩ
5KΩ
Refers
figure.
Weltrend Semiconductor, Inc.
Page 9
following
10KΩ
5V
10KΩ
GND2
the
2V
GND1
GND
WT9051
Data Sheet REV1.0
29
SDA
Input the serial data, and
outputs the acknowledge of
the I 2 C bus.
Vcc
10uA
10KΩ
20uA
5KΩ
5V
5KΩ
29
0V
100KΩ
GND2
30
SCL
Input the serial clock of I 2 C
bus. The clock frequency Vcc
corresponds to 400 KHZ
GND1
10uA
20uA
5V
10KΩ
5KΩ
0V
5KΩ
30
GND2
Weltrend Semiconductor, Inc.
Page 10
GND1
WT9051
Data Sheet REV1.0
Picture Image of Correction
Vertical Output Stage
Function
Output Control Control
Output Wave form
Pin
Sub
Condition
Address
Vertical
Size 4
0BHEX
00HEX
Correction
D7~D0
(8bits)
Image
2.0Vp-p
FFHEX
3.0Vp-p
Vertical Linearity 4
S Correction
0DHEX
D6~D0
(7bits)
01HEX
240mVp-p
3.0Vp-p
7FHEX
240mVp-p
3.0 Vp-p
Vertical Linearity 4
C Correction
0EHEX
D6~D0
(7bits)
01HEX
135mVp-p
3.0Vp-p
7FHEX
135mVp-p
3.0Vp-p
Notice: 1. The output amplitude depends on vertical saw wave amplitude(“output amplitude” shows the
wave form when the vertical saw wave is 3.0 Vp-p)
2. Vertical Linearity S or C corrections are OFF status when DAC value is 00H.
Weltrend Semiconductor, Inc.
Page 11
WT9051
Data Sheet REV1.0
E/W Output Stage
Function
Trapezoid
Correction
Control
Output Control Control
Inside Wave form
Pin
Sub
Condition
Address
01HEX
5
0AHEX
D6~D0
(7bits)
5VDC
0.56Vp-p
Image
7FHEX
0.56Vp-p
5VDC
Side
Correction
Control
Pin 5
09HEX
D6~D0
(7bits)
00HEX
5VDC
0Vp-p
1.45Vp-p
7FHEX
Side Pin Corner 5
Top Correction
Control
07HEX
D6~D0
(7bits)
00HEX
5VDC
5VDC
0.34Vp-p
7FHEX
0.34Vp-p
Side Pin Corner 5
Bottom
Correction
Control
08HEX
D6~D0
(7bits)
00HEX
5VDC
5VDC
0.34Vp-p
7FHEX
0.34Vp-p
5VDC
Notice1The output amplitude depends on vertical saw wave amplitude(output amplitude shows the
waveform when the vertical is 3.0Vp-p.2. Trapezoid or side pin correction is OFF status when DAC
value is 00H.3Side Pin Corner Top/Bottom is 0FF status when both DAC(SPCT and SPCB)value are
00H.
Weltrend Semiconductor, Inc.
Page 12
WT9051
Data Sheet REV1.0
Horizontal Phase Stage
Function
Parallelogram
Correction
Control
Output Control Control
Inside Wave form
Pin
Sub
Condition
Address
01HEX
-04HEX
D6~D0
(7bits)
2.5VDC
0.48Vp-p
Image
7FHEX
0.48Vp-p
2.5VDC
Side
Balance
Correction
Control
Pin --
03HEX
D6~D0
(7bits)
01HEX
2.5VDC
0.46Vp-p
7FHEX
0.46Vp-p
Side Pin Corner -Balance
Top
Correct Control
05HEX
D6~D0
(7bits)
00HEX
2.5VDC
2.5VDC
0.31Vp-p
7FHEX
0.31Vp-p
Side Pin Corner -Balance Bottom
Correction
Control
06HEX
D6~D0
(7bits)
00HEX
2.5VDC
2.5VDC
0.31Vp-p
7FHEX
0.31Vp-p
2.5VDC
Notice: 1. The output amplitude depends on vertical saw wave amplitude(output amplitude shows the
waveform when the vertical is 3.0Vp-p.
2. Trapezoid or side pin Balance correction is OFF status when DAC value is 00H.
3. Side Pin Corner Balance Top/Bottom are 0FF status when both DAC(SPCT and SPCB)value are
00H.
Weltrend Semiconductor, Inc.
Page 13
WT9051
Data Sheet REV1.0
FUNCTIONAL DESCRIPTION
I 2 C Bus Interface
1. Serial Bus(I 2 C Bus)Interface
2
(1) I C Bus Overview
2
The I C bus is a dual bi-directional serial bus, developed by Philips. It is configured with
two lines –a serial data line(SDA)and a serial clock line(SCL).
2
The WT9051 features a built-in I C bus interface circuit,20 8-bit rewritable registers, and
one 8-bit read-only register that is used for indicating the internal status of the IC and so
on. These are used in write mode(slave receive)and read mode(slave transmit).
(2) Data Transmission Format
The transmission format features a sub address in write mode only. Data is configured in 8-bit
units, after which an acknowledge bit must be appended. Note that data transmission is performed
by transmitting the most significant bit(MSB)first.
The data to be transmitted immediately after the issue of the start conditions is the slave
address used to select the address of the WT9051.This address is configured using seven
bits, with the remaining one bit being the data direction bit, used to set the direction of the
subsequently transmitted data. Read involves transferring data from the WT9051 to the master
device, while write involves transferring data from the master device to the WT9051.
Set 1 for read, or 0 for write. An example of the data transfer format is shown below.
1.Write Mode(Slave Receive)
The slave address is read into the first byte, the sub address is read into the second byte,
while the data can be read into the third and subsequent bytes. By using the sub address
auto-increment function, data can be read out continuously.
(A)1-byte transfer format
STA
SLV
7bit
W
A
1bit
SUB
1bit
A
8bit
DATA
1bit
A
8bit
STP
1bit
(B) Continuous byte transfer format
STA
SLV
7bit
W
1bit
A
SUB
1bit
A
8bit
DATA1
1bit
DATA
8bit
Weltrend Semiconductor, Inc.
Page 14
A
8bit
A
1bit
1bit
STP
WT9051
Data Sheet REV1.0
2.Read Mode(Slave Transmit)
The slave address is transmitted from the first byte and data is transmitted from the second and
subsequent bytes. When no acknowledgement bit is received from the master device, release the SDA
line. Do not return an acknowledge signal before issuing the stop conditions.
STA
SLV
R
7bit
1bit
*Remarks
・STA :Start condition
・SLV :Slave address
・W/R :Data direction bit
W :Write mode (slave receive)
R :Read mode (salve transmit)
・Data :Data
・Sub :Sub address
・A/NA :Acknowledge bit
A :acknowledge
N :No acknowledge
A
1bit
DATA
NA
8bit
STP
1bit
STP :Stop condition
(3) V Period Transfer Mode
The WT9051 is provided with a switch (05H :D7)for setting whether rewriting DAC of the WT9051
is performed in free-run mode or in sync with the V-Sync signal.
・05H :D7 =“0 ”→ Rewriting is performed in free-run mode.
Data is changed while the screen is being displayed, such that if the VSAW amplitude or position
data is changed, horizontal noise lines will appear on the screen.
・05H :D7 =“1 ”→ Rewriting is performed in sync with the V-Sync signal.
Data is changed in the BLK period, such that horizontal noise lines do not appear on the screen.
This technique can be used only to convert the following four items of vertical data.
1.Vertical size control (0BH : D7 to D0)
2.Vertical position control (0CH : D7 to D0)
3.Vertical S linearity (0DH : D6 to D0)
4.Vertical C linearity (0EH : D6 to D0)
*Note on data rewriting in V period transfer mode
When V period transfer mode is used, automatic increment cannot be used.
Only one item of data can be received for each 1V.The second and subsequent items of data are
discarded until BLK is received again. When automatic increment is used, only one item of data
Weltrend Semiconductor, Inc.
Page 15
WT9051
Data Sheet REV1.0
Address Table
1.Slave Address
Mode
White
Read
D7
1
1
D6
0
0
D5
0
0
D4
0
0
D3
1
1
D2
1
1
D1
0
0
D0
0
1
2. SUB ADDRESS
2-1 Write Mode
sub
D7
Address
00HEX X-ray
Protector(XP)
0:normal
<1:reset>
01 HEX
<>: initial condition at power on reset
D6
0:exhibit
1:inhibit
<1>
04 HEX
05 HEX
06 HEX
D4
H OUT
PWN OUT
Control(HO) Control(PO)
0:exhibit
1:inhibit
D3
D2
D1
D0
HORIZONTAL DUTY(HDUTY)
<1>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
SIDE PIN BALANCE <SPB>
<0>
<0>
<0>
<0>
<0>
<0>
Horizontal Size <HSIZE>
<0>
02 HEX
03 HEX
D5
<0>
<0>
<0>
Horizontal Position<HPOSI>
<1>
<0>
V.BLK
Width<VBW>
<0:short>
1:long
<1>
DF.OUT
SELECT
0:SEP.
<1:MIX>
<1>
V.Period Transfer
Mode
<0:Off>
1:On
<1>
Unused
<0>
<0>
<0>
<0>
<0>
PARALLELOGRAM <PARA>
<0>
<0>
<0>
<0>
SIDE PIN CORNER BALANCE TOP <SPCBT)
<0>
<0>
<0>
<0>
<0>
<0>
SIDE PIN BALANCE BOTTOM(SPCBB)
<0>
<1>
07 HEX
08 HEX
09 HEX
Clamp Pulse
Position<CP>
<0:Trailing>
1:Leading
V-BLKACI amp
Select<BCI>
<0:BLK+CLP>
1:Select2
V-BLKA CIamp
Select2<BC2>
<0:BLK>
1:CLP
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
SIDE OIN CORNER TOP<SPCT>
<1>
<0>
<0>
<0>
<0>
SIDE PIN CORNER BOTTOM<SPCB>
<1>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
SIDE PIN<SP>
<1>
<0>
<0>
Weltrend Semiconductor, Inc.
Page 16
WT9051
Data Sheet REV1.0
Sub
Address
0A HEX
D7
D6
FHOSC Max.
Frequency
<0:100kHz>
1:150kHz <1>
0B HEX
D3
D2
<0>
<0>
<0>
Vertical Size <Vsize>
<0>
<0>
<0>
<0>
<0>
<0>
Vertical Position <VPOSI>
<0>
<0>
<0>
<1>
Unused
<0>
<0>
<0>
<0>
Vertical Linearity S<VLS>
<0>
<0>
<0>
<1>
<0>
<0>
<0>
Vertical Linearity C<VLC>
<0>
<0>
<0>
<1>
<0>
<0>
<0>
<0>
Horizontal Moire cancellor <HMC>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
Vertical Moire cancellor <VMC>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
<0>
Horizontal Dynamic Focus Amplitude<HDFA>
<0>
<1>
<0>
<0>
<0>
<0>
Horizontal Dynamic Focus Phase<HDFP>
<0>
<0>
<0>
<0>
<0>
Vertical Dynamic Focus Amplitude<VDF>
<0>
Unused
<1>
<0>
13 HEX
<0>
<1>
<0>
10 HEX
11 HEX
D0
<0>
12 HEX
0F HEX
D1
Trapezoid <TRAP>
<0>
HEHT-fH
Tracking
EW-HSIZE
Tracking
<0:Track>
1:Unrack
EW-fH
Tracking
0:Untrack
<1:Track>
HDF-HSIZE
Tracking
<0:Untrack>
1:Track
Unused
0E HEX
D4
<1>
0C HEX
0D HEX
D5
<0>
<0>
<0>
<0>
<0>
<0>
<0>
2-2 Read Mode
Sub Address
00HEX
D7
Unused
D6
Unused
D5
Unused
D4
Unused
D3
Unused
<0>
<0>
<0>
<0>
<0>
Weltrend Semiconductor, Inc.
Page 17
D2
Power On
Reset
0:Power on
1:Power Off
D1
H Lock
Detector
0:Lock
1:Unlock
D0
X-ray
Detector
0:Undetct
1:Detect
WT9051
Data Sheet REV1.0
Details of Each Sub Address
Those value in carets <>indicate the settings at a Power On Reset.
Write Mode
1.Sub address 00H
Sub
Address
00HEX
D7
D6
X-ray
Protector(X
P)
0:Normal
<1:Reset>
H OUT
Control(HO)
<0:Exhibit>
1:Inhibit
D5
D4
PWM OUT
Control(PO)
<0:Exhibit>
1:Inhibit
D3
D2
D1
D0
Horizontal DUTY <HDUTY>
<1>
<0>
<0>
<0>
<0>
D7: X-ray protector
When the input of Pin19 is over 5V,X-ray protection circuit is active. So the output of the
horizontal output signal(H-OUT)from Pin17 and the output of the PWM pulse (PWMO) from Pin14
disappear.
D6: H-OUT Control
Bit for controlling the output of the horizontal output signal (H-OUT) from Pin17.
When this bit is set to 0,output is possible. When this bit is set to 1,output is disabled.
D5: PWM OUT Control
Bit for controlling the output of the PWM pulse for high voltage control from Pin14.
When this bit is set to 0,output is possible. When this bit is set to 1,output is disabled.
D4 to D0: Horizontal DUTY (HDUTY)
Bit for controlling the duty of the horizontal output signal, output from Pin17.
The duty can be held to roughly will be large.
Sub
Address
01HEX
D7
<1>
D6
<0>
D5
<0>
D4
D3
D2
D1
D0
<0>
<0>
<0>
D2
D1
D0
Horizontal Position<HPOSI>
<0>
<0>
<0>
<0>
<0>
Horizontal Size <HSIZE>
<0>
<0>
D7 to D0: Horizontal Size (HSIZE)
Bit for controlling the horizontal size.
This data is used to modify the DC voltage of the waveform output from Pin5.
Sub
Address
02 HEX
D7
<1>
D6
D5
<0>
<0>
D4
D3
D7 to D0: Horizontal Position (HPOSI) Bit for controlling the horizontal position. Based on this data, the
horizontal oscillator signal (Pin17)for the horizontal sync input signal
can be converted.
Weltrend Semiconductor, Inc.
Page 18
WT9051
Data Sheet REV1.0
Sub
D7
D6
Address
03HEX V.BLK
Width<VBW>
<0:Short>
1:long
<1>
D5
D4
D3
D2
D1
D0
<0>
<0>
Side Pin Balance<SPB>
<0>
<0>
<0>
<0>
D7: V BLK Width
Bit for selecting the vertical blanking pulse width.
When this bit is set to 0, the width is short pulse width. When this bit is set to 1,the width
is long pulse width.
D6 to D0: Side Pin Balance (SPB)
The amount of compensation for the side pin balance can be set using the seven bits from D6 to
D0.The initial value is 40HEX .The variable range is from 01HEX to 7FHEX. When the value is 00HEX Side
Pin Balance correction is OFF status.
Sub
Address
04HEX
D7
DF.OUT
Select
0:sep.
<1:Mix>
D6
D5
D4
D3
D2
D1
D0
Parallelogram <PARA>
<1>
<0>
<0>
<0>
<0>
<0>
<0>
D7: DF.OUT Select
Bit for selecting the output of the parabola wave for dynamic focus signal from Pin8.
When this bit is set to 0,output the vertical dynamic focus signal from Pin8. When this bit is set to
1,output the mixed signal of the horizontal and vertical dynamic focus from Pin8.
D6 to D0: Parallelogram (PARA)
The amount of compensation for the horizontal square wave is set using the seven bits from D6 to
D0.The initial value is 40HEX the variable range is from 01HEX to 7FHEX . When the value is 00HEX
Parallelogram correction is OFF status.
Sub
Address
05HEX
D7
V Period
Transfer
Mode
<0:Off>
1:On
D6
D5
D4
D3
D2
D1
D0
Side Pin Corner Balance Top<SPCRT>
<1>
<0>
<0>
<0>
<0>
<0>
<0>
D7: V.Period Transfer Mode Bit for setting whether I 2 C-Bus write data transfer is performed in free-run
mode or in sync with the V-Sync signal. When this bit is set to 0,data transfer is performed in free-run
mode. When this bit is set to 1,data transfer is performed in sync with the V-Sync signal.
D6 to D0: Side Pin Corner Balance Top(SPCBT)The amount of compensation for the side pin corner
balance top can be set using the seven bits from D6 to D0.The initial value is 40HEX .The variable range
is from 00HEX to 7FHEX .When this value and Side Pin Corner Balance Bottom DAC value is 00HEX ,Side
Pin Corner Balance Top correction is OFF status.
Weltrend Semiconductor, Inc.
Page 19
WT9051
Data Sheet REV1.0
Sub
Address
06HEX
D7
D6
D5
Unused
<0>
D4
D3
D2
D1
D0
Side Pin Corner Balance Bottom<SPCBB>
<1>
<0>
<0>
<0>
<0>
<0>
<0>
D7: Unused
D6 to D0: Side Pin Corner Balance Bottom (SPCBB)
The amount of compensation for the side pin corner balance bottom can be set using the seven bits
from D6 to D0. The initial value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is
00HEX and Side Pin Corner Balance Top DAC value is 00HEX, Side Pin Corner Balance Bottom correction
is OFF status.
Sub
D7
Address
07HEX Clamp Pulse
D6
D5
D4
D3
D2
D1
D0
Side Pin Corner Top<SPCT>
Position<CP>
<0:Trailing>
1:Leading
<1>
<0>
<0>
<0>
<0>
<0>
<0>
D7: Clamp Pulse Position
Bit for tuning the clamp pulse signal output.
When this bit is set to 0, the clump pulse is output at the trailing edge of the horizontal sync input signal.
When this bit is set to 1, the clump pulse is output at the leading edge of the horizontal sync input signal.
D6 to D0: Side Pin Corner Top (SPCT)
The amount of compensation for the side pin corner top can be set using the seven bits from D6 to D0.
The initial value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is 00HEX and Side
Pin Corner Balance Top DAC value is 00HEX, Side Pin Corner Top correction is OFF status.
Sub
D7
Address
08HEX V-BLK&Clamp
Select1 (BC1)
<0:BLK+CLP>
1: Select 2
D6
D5
D4
D3
D2
D1
D0
<0>
<0>
Side Pin Corner Bottom<SPCB>
<1>
<0>
<0>
<0>
<0>
D7: V-BLK&Clamp Select1
Bit for selecting the output from Pin (BLKO)
When this bit is set to 0,the vertical blanking pulse and the clamp pulse are output.
When this bit is set to 1, this output depends on the bit D7 of the sub address”09”
D6 to D0: Side Pin Corner Bottom (SPCB)
The amount of compensation for the side pin corner bottom can be set using the seven bits from D6 to
D0. The initial value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is 00HEX and
Side Pin Corner Top DAC value is 00HEX, Side Pin Corner bottom correction is OFF status.
Weltrend Semiconductor, Inc.
Page 20
WT9051
Data Sheet REV1.0
Sub
D7
D6
Address
09HEX V-BLK&CIamp
Select2<BC2>
(0: BLK)
<0>
1:CLP
D5
D4
D3
D2
D1
D0
Side Pin<SP>
<0>
<0>
<0>
<0>
<0>
<0>
D7: V-BLK&Clamp Select2
Bit for selecting the output from Pin28 (BLKO)
When this bit is set to 0,the vertical blanking pulse is output
When this bit is set to 1, the clamp pulse is output.
D6 to D0: Side Pin (SP)
The amount of compensation for the side pin can be set using the seven bits from D6 to D0. The initial
value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is 00HEX, Side Pin correction
is OFF status.
Sub
D7
D6
Address
0AHEX fH OSC Max
Frequency
<0:100kHz>
1:150kHz
<1>
D5
D4
Trapezoid
<0>
<0>
D3
D2
D1
D0
<0>
<0>
<TRAP>
<0>
<0>
D7: fH OSC Max. Frequency
Bit for setting the maximum horizontal oscillation frequency.
When this bit is set to 0, the maximum oscillation frequency is 100kHz. When this bit is set to 1, the
maximum oscillation frequency is 150kHz.
D6 to D0: Trapezoid (TRAP)
The amount of trapezoid is set using the seven bits from D6 to D0. The initial value is 40HEX. The
variable range is from 00HEX to 7FHEX. When this value is 00HEX, Trapezoid correction is OFF status.
Sub
Address
0BHEX
D7
D6
D5
D4
D3
D2
D1
<0>
<0>
D0
Vertical Size <VSIZE>
<1>
<0>
<0>
<0>
<0>
<0>
D7 to D0: Vertical Size (VSIZE)
Bit used for controlling the vertical size.
The input data is used to control the amplitude of the vertical sawtooth waveform output from Pin4. The
initial value is 80HEX. The variable range is from 00HEX to FFHEX.
Sub
Address
0CHEX
D7
D6
D5
D4
D3
D2
D1
D0
<0>
<0>
<0>
Vertical Position <VPOSI>
<1>
<0>
<0>
<0>
<0>
D7 to D0: Vertical Position (VPOSI)
Bit for controlling the vertical position.
The Data is used to control the DC voltage of the vertical sawtooth waveform output from Pin4.
Weltrend Semiconductor, Inc.
Page 21
WT9051
Data Sheet REV1.0
Sub
Address
0DHEX
D7
D6
D5
Unused
<0>
D4
D3
D2
D1
D0
<0>
<0>
Vertical Linearity S<VLS>
<1>
<0>
<0>
<0>
<0>
D7: Unused
D6 to D0: Vertical Linearity S (VLS)
Bits D6 to D0 are used to set the amount of vertical S compensation.
The compensation signal is mixed with the vertical SAW waveform output from Pin4, then output. The
initial value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is 00HEX, Vertical
Linearity S correction is OFF status.
Sub
Address
0EHEX
D7
HEHT-fH
Tracking
0:Untrack
<1:Track>
D6
D5
D4
D3
D2
D1
D0
<0>
<0>
Vertical Linearity C<VLC>
<1>
<0>
<0>
<0>
<0>
D7: HEHT-fH Tracking
Bit for selecting whether HEHT gain is tracking to horizontal frequency or not. This function works on
EW fH Tracking (10H:D7)=1 and this bit =1. If EW fH Tracking (10H:D7)=0, this function does not work.
D6 to D0: Vertical Linearity C (VLC)
Bits D6 to D0 are used to set the amount of vertical C compensation.
The compensation signal is mixed with the vertical SAW waveform output from Pin4, then output. The
initial value is 40HEX. The variable range is from 00HEX to 7FHEX. When this value is 00HEX, Vertical
Linearity C correction is OFF status.
Sub
Address
0FHEX
D7
EW-HSIZ
E
Tracking
<0:Track>
1:Untrack
D6
D5
D4
D3
D2
D1
D0
<0>
<0>
Horizontal Moire Cancellor <HMC>
<0>
<0>
<0>
<0>
<0>
D7: EW-HSIZE
Bit for selecting whether E/W output is tracking to HSIZE or not.
When this bit is set to 0, E/W output is tracking to HSIZE. When this bit is set to 1, E/W output is not
tracking to HSIZE.
D6 to D0: Horizontal Moire Cancellor (HMR)
Bits D6 to D0 are used to set the compensation amount for H moiré cancel.
When the value is 00HEX, horizontal Moire Cancellor is OFF status.
Weltrend Semiconductor, Inc.
Page 22
WT9051
Data Sheet REV1.0
Sub
Address
10HEX
D7
D6
EW-fH
Tracking
0:Untrack
<1:Track> <0>
D5
D4
D3
D2
D1
D0
Vertical Moire Cancellor <VMC>
<0>
<0>
<0>
<0>
<0>
<0>
D7: EW-fH Tracking
Bit for selecting whether E/W output is tracking to horizontal frequency or not.
When this bit is set to 0, E/W output is tracking to horizontal frequency. When this bit is set to 1, E/W
output is not tracking to horizontal frequency.
D6 to D0: Vertical Moire Cancellor (VMC)
Bits D6 to D0 are used to set the compensation amount for V moiré cancel.
When the value is 00HEX, Vertical Moire Cancellor is OFF status.
Sub
Address
11HEX
D7
D6
D5
HDF-HSIZE
Tracking
<0:Untrack>
1:Track
<1>
D4
D3
D2
D1
D0
Horizontal Dynamic Focus Amplitude<HDFA>
<0>
<0>
<0>
<0>
<0>
<0>
D7: HDF-HSIZE Tracking
Bit for selecting whether HDF output is tracking to HSIZE or not.
When this bit is set to 0, HDF output is tracking to HSIZE. When this bit is set to 1, HDF output is not
tracking to HSIZE.
D6 to D0: Horizontal Dynamic Focus Amplitude (HDFA)
Bits D6 to D0 are used to set the amplitude of the dynamic focus parabola.
When the value is 00HEX, Horizontal Dynamic Focus is OFF status.
Sub
Address
12HEX
D7
D6
D5
Unused
<0>
D4
D3
D2
D1
D0
<0>
<0>
Horizontal Dynamic Focus Phase<HDFP>
<1>
<0>
<0>
<0>
<0>
D7: Unused
D6 to D0: Horizontal Dynamic Focus Phase (HDFP)
Bits D6 to D0 are used to set the amount of compensation for the dynamic focus phase.
Sub
Address
13HEX
D7
D6
D5
Unused
<0>
D4
D3
D2
D1
D0
<0>
<0>
Vertical Dynamic Focus Amplitudes<VDF>
<1>
<0>
<0>
<0>
<0>
D7: Unused
D6 to D0: Vertical Dynamic Focus Amplitude (VDF)
Bits D6 to D0 are used to set the amplitude of the dynamic focus parabola.
When the value is 00HEX, Vertical Dynamic Focus is OFF status.
Weltrend Semiconductor, Inc.
Page 23
WT9051
Data Sheet REV1.0
Read Mode
Sub
Address
00HEX
D7
D6
D5
D4
D3
Unused
Unused
Unused
Unused
Unused
<0>
<0>
<0>
<0>
<0>
D2
D1
Power On
H. Lock
Reset
Detector
0: Power on 0: Lock
1: Power off 1: Unlock
D0
X-ray
Detector
0: Undetect
1: Detect
D7 to D3: Unused
D2: Power On Reset
Used to detect a power on reset. When a power on reset is applied, this bit is set to 1.
Usually, set this bit to 0.Immediately after power-on, or if the power supply voltage ever drops
below around 6.5V(low →high)or 6.2V(high →low),this bit is set to 1.After this bit has been
set to 1, it should be cleared to 0 after two read cycles, provided the 12V power is applied
normally. If, for example, the 12V power is not applied, no matter how many times read is performed,
this bit will not be cleared to 0 and instead will remain set to 1.
D1: H Lock Detector
Used to detect the Lock status of the horizontal sync signal and the oscillator output. In the
lock status, this bit will be set to 0.In the unlock status, this bit will be set to 1.
D0: X-ray Detector
Used to detect the X-ray protection. When the X-ray protection circuit is active, this bit is
set to 1.Usually, set this bit to 0.
Weltrend Semiconductor, Inc.
Page 24
WT9051
Data Sheet REV1.0
OPERATION DESCRIPTION
Automatic Sync. Processing System Sequence
System Block Diagram
18pin FBP
DAC
Auto Sync.
System
H-IN
H-OSC
25pin HLO
WT9051
Processing Sequence
H-out: oscillate in horizontal
minimum frequency (when
no input signal)
AutoSync Operation
Start
(Trigger:V-In)
Compare H-In frequency and
H-OSC frequency
H-In Freq=H.OSC
Freq.?
No
Counter 1 bit up
H-Out Freq-Up
YES
Counter OFF. AFC On
AFC Lock in 5
vertical term
Court down using H-OSC
YES
Down to minimum freq.
25 Pin “H”
Auto Sync
finish
17pin Hout
Operation
H-in freq change OR H-in no input
Weltrend Semiconductor, Inc.
Page 25
WT9051
Data Sheet REV1.0
Notice
1) Automatic Sync. system can ’t start count up operation without vertical sync signal input.
The start trigger of count up operation is vertical sync signal input.
2) WT9051 oscillates in minimum free-run frequency during no signal status. Please input desirable
frequency quasi-pulse from MCU to WT9051during no signal status.
3) Please input no signal term for at least 3m sec in changing frequency at any time (Please show
in the following figure.).In the following figure,f1 and f2 means a horizontal input signal
which corresponds to a mode or quasi-pulse signal from MCU.
f1
f2
H-In
No signal term = at least 3m sec
TIMING CHART
The timing of horizontal stage is set by ratio to horizontal frequency (fH ).For example, if
the delay time is 10 μs and fH is 30kHz,the ratio is 30%.
TID : I 2 C bus control this delay time.
The control range is form 16%to 43%.
THW : The pulse width of signal to the AFC.
This value is 10%.
TFBP : This delay time is 30%from the rising edge of the fly back pulse.
Horizontal sync
Signal input
Threshold voltage
TID
AFC internal pulse
THW
AFC filter waveform
Fly back delay
internal pulse
TFBP
Fly back pulse
input signal
Threshold voltage
Weltrend Semiconductor, Inc.
Page 26
WT9051
Data Sheet REV1.0
Vertical Blanking Pulse (V-BLK)and Video Clamp Pulse (CLAMP)Generator
The WT9051 has an on-chip circuit that generates vertical blanking pulse and clamp pulse.
The output signal mode must be selected by I 2 C bus. Figure illustrates the output signal. (WT9051)
was selecting with outside the putting device. WT9051 was only mixed signal output. However,
WT9051 can be simply selected with the bus.)
The vertical blanking pulse width must be selected by I 2 C bus. It is 288 μs (typical)or 335
μs (typical).The video clamp pulse width is 0.8 μs (typical). (Provided that 20pin resistor is set to 47K
Ω.
The clamp pulse can choose the leading edge or the trailing edge of the horizontal sync by I2C BUS.
1. mixed signal output
5Vpp
2Vpp
GND
CLAMP width
V-BLK width
2. clamp pulse (CLAMP) output
5Vpp
GND
CLAMP width
3. vertical blanking pulse (V-BLK) output
5Vpp
V-BLK width
GND
Weltrend Semiconductor, Inc.
Page 27
WT9051
Data Sheet REV1.0
MOIRE Canceller
1. Vertical MOIRE canceller
It divides V-IN.
The MOIRE can be canceled when shifting a vertical position by this signal.
2
The shift value can be controlled by I C bus.
2.Horizontal MOIRE canceller
It divides FBP.
And, it generates the signal, which reversed a phase every other vertical period.
The MOIRE can be canceled when shifting a horizontal position by this signal.
2
The shift value can be controlled by I C bus.
V-IN
(Vertical input)
V MOIRE cancel
signal (A point)
FBP -IN
Divided signal
(B point)
H MOIRE cancel
Signal (C point)
A
V-IN
1/2 Divider
V-POSITION
B
C
FBP-IN
1/2 Divider
V-POSITION
Weltrend Semiconductor, Inc.
Page 28
WT9051
Data Sheet REV1.0
4.5 PWM for B+ control
The PWM Block consists of the error amplifier, and the flip-flop, the oscillator.
1. Error amplifier
The error amplifier is the transconductance amplifier type. The non-inverting input is
connected to the pin11.The non-inverting input is connected to the reference voltage (=2.5Volts).
The output is connected to pin12 and the comparator, the clamp. The clamp limits the maximum
output voltage to 5.0Volts.
2. Oscillator
The external capacitor is charged by a external resistor. When the flip-flop is reset, it is
discharged. The discharge is done until it becomes limit voltage (=1.0Volts).
3. Flip-Flop
This flip-flop will be set at the rising edge of the H-OUT. When the charging voltage (pin13)
of the condenser becomes equal to the output voltage (pin12)of the error amplifier, the output
of the comparator resets a flip-flop.
4. Inhibit mode
It doesn't output in the following case.
・When the X-ray protection becomes active.
・When lower than the voltage of Power On Reset.
2
・When setting to off by I C Bus.
Weltrend Semiconductor, Inc.
Page 29
WT9051
Data Sheet REV1.0
Tracking Specifications
Tracking specifications of each waveform and function are shown in the following.
*) “ ( ) “ stands for ON/OFF switch for tracking function.
Waveform/Function
VSAW Amplitude
Vertical S-Linearity
Vertical C-Linearity
Trapezoid
Side Pin
Side Pin Corner Top
Side Pin Corner Bottom
Vertical Dynamic Focus
Horizontal Dynamic Focus
EW DC
V-EHT Gain
H-EHT Gain
Tracking items
VSIZE, V-EHT
VSIZE, VPOSI, V-EHT
VSIZE, VPOSI, V-EHT
VSIZE, VPOSI, V-EHT, HSIZE(0FH:D7), fH(10H:D7)
VSIZE, VPOSI, V-EHT, HSIZE(0FH:D7), fH(10H:D7)
VSIZE, VPOSI, V-EHT, HSIZE(0FH:D7), fH(10H:D7)
VSIZE, VPOSI, V-EHT, HSIZE(0FH:D7), fH(10H:D7)
VSIZE, VPOSI, V-EHT
HSIZE(11H:D7)
HSIZE, fH(10H:D7), H-EHT
VSIZE
FH(10H:D7)
Details of Tracking Specifications
1.EW output tracking to HSIZE
1
HSIZE-DAC vs EW amplitude
HSIZE-DAC small
EW Amp
big
big
samll
EW.Amp
HSIZE-DAC
2
3
On/Off Switch of this function
Sub address 0FH:D7
“0”: Track(Initial)
“1”:Untrack
Note
When HSIZE-DAC is changed form FFH to 00H. EW amplitude becomes bigger 30%
2.HDF output tracking to HSIZE
1
HSIZE-DAC vs.
HDF amplitude
HSIZE-DAC small
HDF Amp.
big
big
samll
HDF.Amp
HSIZE-DAC
2
3
On/Off Switch of this function
Sub address 11H:D7
“0”: Track(Initial)
“1”:Untrack
Note
When HSIZE-DAC is changed form FFH to 00H. HDF amplitude becomes bigger 70%
Weltrend Semiconductor, Inc.
Page 30
WT9051
Data Sheet REV1.0
3. EW output tracking to horizontal frequency
1
Horizontal frequency vs. EW DC voltage
FH
EW DC
low
low
high
high
EW DC
fH
2
3
On/Off Switch of this function
Sub address 10H:D7
“0”: Untrack (Initial)
“1”:track
Note
Formula for EW DC voltage EW DC=((fH/100k-1)x 0.325+1)x 5V
4. H-EHT Gain tracking to horizontal frequency
1
Horizontal frequency vs. Gain(=△EWO/△HEI)
FH
Gain
low
small
high
big
△ EWO/
△HEI
fH
2
On/Off Switch of this function
Sub address 0FH:D7(only on the condition that the data of sub address 10H:D7 is “1”
“1”: Track (Initial)
“0”:Untrack
Weltrend Semiconductor, Inc.
Page 31
WT9051
Data Sheet REV1.0
Electrical Characteristics
。
Absolute Maximum Ratings (Unless otherwise specified, Ta=25 C)
Parameter
Symbol
Condition
Power Supply
VCC
Input Voltage of pin16
SDA Input Voltage
VSDA
Input Voltage Range of pin29
SDA Output Sink Current
ISDA
Output sink current of pin29
SCL Input Voltage
VSCL
Input Voltage Range of pin30
VSAW Output Source Current
IVSAWO
Output Source Current of pin4
VSAW Output Sink Current
IVSAWI
Output Sink Current of pin4
E/W Output Source Current
IEWO
Output Source current of pin5
VEI Input Voltage
VVEI
Input Voltage Range of pin6
HEI Input Voltage
VHEI
Input Voltage Range of pin7
BAMPI Input Voltage
VBAMPI
Input Voltage Range of pin11
BAMPO Input Voltage
VBAPO
Input Voltage Range of pin12
PWM Output Sink Current
IPWMI
Output Sink Current of pin14
V.DF Output Source Current
IVDF1
Output Source Current of pin8
H.DF Output Source Current
IHDF1
Output Source Current of pin9
Fly Back Pulse Input Voltage
VFBP
Input Pulse Voltage Range of pin18
Horizontal Output Sink Current
IHOUTI
Output Sink Current of pin17
Horizontal Input Voltage
VHIN
Input Pulse Voltage Range of pin26
Vertical Input Voltage
VVIN
Input Pulse Voltage Range of pin27
BLK&CLP Output Source Current
IBLK
Output Source Current of pin28
Permissible package power dissipation Pd
Ta=70。C, RTH=55。C
Operating ambient temperature
Ta
Storage temperature
TSTG
Rating
14
-0.2~Vcc
10
-0.2~Vcc
4.5
4.5
4.5
-0.2~Vcc
-0.2~Vcc
-0.2~Vcc
-0.2~Vcc
10
4.5
4.5
-0.2~Vcc
10
-0.2~Vcc
-0.2~Vcc
4.5
1.0
-10~+75
-40~+125
Unit
V
V
mA
V
mA
mA
mA
V
V
V
V
mA
mA
mA
V
mA
V
V
mA
W
。C
。C
Notice:
If the absolute maximum rating of even one of the above parameters is exceeded even momentarily,
the quality of the product may be degraded. In other words, absolute maximum ratings specify the
values exceeding which the product may be physically damaged. Be sure to use the product with these
ratings never exceeded. In addition, pins not listed in the above table must also be used in a
range of 0 to Vcc .
。
RECOMMENDED OPERATING RANGE(Vcc=12V, Ta=25 C, Vcc=12V, unless otherwise noted)
Parameter
Symbol Test Condition
MIN TYP MAX
Supply Voltage
VCC
Pin16 input voltage
11.5 12.0 12.5
SDA Input Low Level
VSDAL
Pin29 input low level
0
0
1.5
SDA Input High Level
VSDAH Pin29 input high level
2.3
5
5
SCL Input Low Level
VSCLL
Pin30 input low level
0
0
1.5
SCL Input High Level
VSCLH
Pin30 input high level
2.3
5
5
Horizontal Operating Frequency FH
Pin26 input frequency
30
150
Range
Unit
V
V
V
V
V
KHz
Horizontal Input Duty Ratio1
DHIN1
Horizontal Input Duty Ratio2
DHIN2
Vertical Operating Frequency Fv
Range
Vertical Input Pulse Width
W VIN1
Pin26 input pulse duty ratio
amplitude=5Vp-p input polarity: positive
Pin26 input pulse duty ratio amplitude
=5Vp-p input polarity: Negative
Pin27 Input Frequency
Pin27 Input Pulse duty ratio amplitude
=5Vp-p Input Polarity: Positive
Weltrend Semiconductor, Inc.
Page 32
-
-
20
%
60
-
-
%
50
-
200 Hz
-
-
580 us
WT9051
Data Sheet REV1.0
ELECTRONICAL CHARACTERICS(TA=25。C, Vcc=12V, unless otherwise noted)
<Common>
Parameter
Supply Current
Reference Voltage
Power on reset voltage1
(LowÆHigh)
Power on Reset Voltage2
(HighÆLow)
SDA Input Threshold
Voltage1
SDA Input Threshold
Voltage2
MIN
60
4.5
6.0
TYP
69
5.0
6.5
MAX
81
5.5
7.0
VPORL
Test Condition
Supply current of pin16 no signal
Pin20
Input Vcc from 0V to 12V.Judged by
existence of ACK
Input level from 0V to 5V
5.7
6.2
6.7
V
VSDA1
Input level from 0V to 5V
1.7
2.0
2.3
V
VSDA2
Input level from 5V to 0V
1.4
1.7
2.0
V
VSCL1
Input level from 0V to 5V
1.7
2.0
2.3
V
VSCL2
Input level from 5V to 0V
1.4
1.7
2.0
V
Horizontal Sync Input Block (measurement at Pin26(HIN)
Parameter
Symbol Test Condition
MIN
Direct input Threshold Voltage
VHTH
Input signal: separate sync direct input
0.4
TYP
0.6
SCL Input Threshold
Voltage1
SCL Input Threshold
Voltage2
Symbol
ICC
VREF
VPORH
Unit
mA
V
V
<Horizontal sync signal processing Unit>
H.IN Delay Block(measurement at Pin24 (HAFC))
Parameter
Symbol Test Condition
HIN Delay Variable 1
T HPD1 HPOSI=00HEX, Difference from pin26
pin24. Ratio with period.fH=30kHz
HIN Delay Variable 2
T HPD2 HPOSI=FFHEX, Difference from pin26
pin24. Ratio with period. fH=30kHz
HIN Delay Variable Amount1
T HPDA1 (THPD2-THPD1)/255 fH=30kHz
HIN Delay Variable 3
T HPD3 HPOSI=00HEX, Difference from pin26
pin24. Ratio with period. fH=150kHz
HIN Delay Variable 4
T HPD4 HPOSI=FFHEX, Difference from pin26
pin24. Ratio with period. fH=150kHz
HIN Delay Variable Amount 2
T HPDA2 (THPD4-THPD3)/255 fH=30kHz
H-WIDH BLOCK(measurement at pin24(HAFC))
Parameter
Symbol Test Condition
H-WIDTH Variable1
T HWD1
FH=30kHz
H-WIDTH Variable2
T HWD2
FH=150kHz
MIN TYP MAX Unit
to 11.5 15.5 19.4 %
to 33.6
40.0
to 36.3
42.0
47.7 %
0.079 0.100 0.121 %/step
TYP
10.0
10.0
AFC BLOCK(measurement at pin24(HAFC))
Parameter
Symbol Test Condition
MIN
Horizontal AFC Pull in Range1
AFC1 Positive Capture Range at FH =30kHz 7.47
Horizontal AFC Pull in Range2
AFC2 Negative Capture Range at FH =30kHz -9.13
Horizontal AFC Pull in Range3
AFC3 Positive Capture Range at FH =150kHz 7.65
Horizontal AFC Pull in Range4
AFC4 Negative Capture Range at FH -9.35
=150kHz
TYP
8.30
-8.30
8.50
-8.50
Page 33
46.4 %
0.083 0.105 0.127 %/step
to 14.3 17.5 20.7 %
MIN
8.5
8.5
Weltrend Semiconductor, Inc.
MAX Unit
0.8 V
MAX Unit
11.5 %
11.5 %
MAX
9.13
-7.47
9.35
-7.65
Unit
%
%
%
%
WT9051
Data Sheet REV1.0
FBP Delay Block(measurement at pin18(FBPIN) and pin24(HAFC))
Parameter
Symbol Test Condition
MIN
FBP Input Threshold Voltage1
VFBP1 Input level from 0V to 5V
2.2
FBP Input Threshold Voltage 2
VFBP2 Input level from 5V to 0V
1.9
FBP Delay
TFBP
Difference from pin18 to pin24.Ratio with 24.3
period
TYP MAX Unit
2.5
2.8 V
2.2
2.5 V
30
30 %
H-OSC Block(measurement at pin17(HOUT)) these value is excluding spread of
external components
Parameter
Symbol Test Condition
MIN TYP MAX Unit
H.free-run frequency 1
FH01
20.38 22.30 24.22 KHz
No input signal pin22 resistor=1.8KΩ
H.free-run frequency 2
FH02
22.92 25.09 27.25 KHz
No input signal pin22 resistor=1.6KΩ
H-OSC frequency 1
FH01
No input signal pin22 is 1V. Pin22
34.4 37.0 39.6 KHz
resistor=1.8KΩ
H-OSC frequency 2
FH02
No input signal when pin22 resistor
135
145
155 KHz
=1.8KΩ
H-Duty Block(measurement at pin17(HOUT))
Parameter
Symbol Test Condition
H-duty 1
HDUTY1 HDUTY=00HEX fH=30kHz
H-duty 2
HDUTY2 HDUTY=10HEX fH=30kHz
H-duty 3
HDUTY3 HDUTY=1FHEX fH=30kHz
H-duty Amount1
HDUTYA1 (HDUTY3-HDUTY1)/31 fH=30kHz
H-duty 4
HDUTY4 HDUTY=00HEX fH=150kHz
H-duty 5
HDUTY5 HDUTY=10HEX fH=150kHz
H-duty 6
HDUTY6 HDUTY=1FHEX fH=150kHz
H-duty Amount 2
HDUTYA2 (HDUTY6-HDUTY4)/31 fH=150kHz
H-Out Block(measurement at collector of transistor attached at pin17)
Parameter
Symbol Test Condition
H-Out Low Level
VHOL
Pull up resistor 20KΩ
Difference from GND Level
H-Out High Level
VHOH
Pull up resistor 20KΩ
Difference from Vcc Level
Weltrend Semiconductor, Inc.
Page 34
MIN
34.3
44.0
53.2
0.590
34.3
44.0
53.2
0.590
TYP
39.0
50.0
60.5
0.694
39.0
50.0
60.5
0.694
MAX
43.7
56.0
67.8
0.798
43.7
56.0
67.8
0.798
MIN
0
TYP
0.2
MAX Unit
0.3 V
-0.2
0
0
Unit
%
%
%
%/step
%
%
%
%/step
V
WT9051
Data Sheet REV1.0
<Vertical sync signal processing Unit>
Vertical Input Block (measurement at pin27(VIN))
Parameter
Symbol Test Condition
Vertical Input Threshold Voltage
VVIN
Threshold voltage of pin27
V Position Block (measurement at pin4(VSAWO))
Parameter
Symbol Test Condition
Vertical Position1
VP01
VPOSI=00H
Vertical Position2
VP02
VPOSI=7FH
Vertical Position3
VP03
VPOSI=FFH
Vertical Position Amount
VP0A
(VP03-VP01)/255
V-SAW Block measurement at pin4(VSAWO))
Parameter
Symbol Test Condition
Vertical Saw wave Amplitude 1
VSAW1 VSIZE=00H
Vertical Saw wave Amplitude 2
VSAW2 VSIZE=FFH
Vertical Saw wave Amplitude
VSAW VSAW1- VSAW2 /255
Amount
V.free-run frequency
FV0
No input signal
V.free-run Amplitude
VSAW0 No input signal
MIN
2.2
TYP
2.5
MAX Unit
2.8 V
MIN
TYP MAX Unit
2.962 3.153 3.348 V
3.325 3.500 3.675 V
3.620 3.847 4.076 V
2.32
2.72 3.15 mV/step
MIN
1.65
2.65
3.27
TYP
2.0
3.0
3.94
MAX
2.35
3.35
4.61
Unit
VP-P
VP-P
mV/step
10
3.2
25
3.6
MIN
225
260
4.5
0.4
4.5
TYP
265
305
5.0
0.6
5.0
MAX
305
350
5.5
0.8
5.5
TYP
-240
MAX Unit
-110 mV
240
370 mV
40 Hz
4.0 V
<V-BLK/CLAMP Pulse unit>
V-BLK/CLAMP Pulse (measurement at pin28)
Parameter
Symbol Test Condition
Vertical Blanking Pulse Width1
TBLK1 VBW=0, 20pin Resistor=47kΩ
Vertical Blanking Pulse Width2
TBLK2 VBW=1, 20pin Resistor=47kΩ
Vertical Blanking Pulse Amplitude VBLK
Video Clamp Pulse Width
TCLP
20pin Resistor=47kΩ
Video Clamp Pulse Amplitude
VCLP
Unit
us
us
VP-P
us
VP-P
<Correction Unit>
Vertical Linearity “s” Correction Block(measurement at pin4(VSAWO), (notice1, 2)
Parameter
Symbol Test Condition
MIN
-370
Vertical Linearity”S”
VS1
VLS=01HEX, VSIZE=FFHEX
Correction Amplitude1
Difference from VPOC at top part
110
Vertical Linearity”S”
VS2
VLS=01HEX, VSIZE=FFHEX
Correction Amplitude2
Difference from VPOC at bottom part
-70
Vertical Linearity”S”
VS3
VLS=40HEX, VSIZE=FFHEX
Correction Amplitude3
Difference from VPOC at top part
-70
Vertical Linearity”S”
VS4
VLS=40HEX, VSIZE=FFHEX
Correction Amplitude4
Difference from VPOC at bottom part
110
Vertical Linearity”S”
VS5
VLS=7FHEX, VSIZE=FFHEX
Correction Amplitude5
Difference from VPOC at top part
-370
Vertical Linearity”S”
VS6
VLS=7FHEX, VSIZE=FFHEX
Correction Amplitude6
Difference from VPOC at bottom part
Vertical Linearity”S”
VS
(VS5-VS1)/126
2.39
Correction Amount
Weltrend Semiconductor, Inc.
Page 35
0
70
mV
0
70
mV
240
370 mV
-240
-110 mV
3.81
5.23 mV/step
WT9051
Data Sheet REV1.0
Vertical Linearity”C” Correction Block(measurement at pin4(VSAWO), (notice1, 3))
Parameter
Symbol Test Condition
MIN
60
Vertical Linearity”C”
VC1
VLC=01HEX, VSIZE=FFHEX
Correction Amplitude1
Difference from VPOC at top part
60
Vertical Linearity”C”
VC2
VLC=01HEX, VSIZE=FFHEX
Correction Amplitude1
Difference from VPOC at bottom part
-100
Vertical Linearity”C”
VC3
VLC=40HEX, VSIZE=FFHEX
Correction Amplitude2
Difference from VPOC at top part
-100
Vertical Linearity”C”
VC4
VLC=40HEX, VSIZE=FFHEX
Correction Amplitude2
Difference from VPOC at bottom part
-210
Vertical Linearity”C”
VC5
VLC=7FHEX, VSIZE=FFHEX
Correction Amplitude3
Difference from VPOC at top part
-210
Vertical Linearity”C”
VC6
VLC=7FHEX, VSIZE=FFHEX
Correction Amplitude3
Difference from VPOC at bottom part
Vertical Linearity”C”
VC
(VC5-VC1)/126
1.55
Correction Amount
H-Size Control Block(measurement at Pin5(EWO), (notice4, 5, 6)
Parameter
Symbol Test Condition
E/W Output DC Voltage1
VEW1
HSIZE=00H, fH-track=off
E/W Output DC Voltage2
VEW2
HSIZE=7FH, fH-track=off
E/W Output DC Voltage3
VEW3
HSIZE=FFH, fH-track=off
E/W Output DC Voltage Amount VEW
(VEW3- VEW1) /255
E/W Output DC Voltage4
VEW4
HSIZE=FFH, fH=30k
E/W Output DC Voltage5
VEW5
HSIZE=FFH, fH=150k
Trapezoid Correction Block(measurement at pin5(EWO), (notice5, 6)
Parameter
Symbol Test Condition
Trapezoid Correction Amplitude1 VTRA1
TRAP=01H , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
Trapezoid Correction Amplitude2 VTRA2
TRAP=01H , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
Trapezoid Correction Amplitude3 VTRA3
TRAP=40H , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
Trapezoid Correction Amplitude4 VTRA4
TRAP=40FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
Trapezoid Correction Amplitude5 VTRA5
TRAP=7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
Trapezoid Correction Amplitude6 VTRA6
TRAP=7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
Trapezoid Correction Amplitude VTRA
V TRA5- VTRA1 /126
Amount
Trapezoid Correction Amplitude7 VTRA7
VTRA5 , HSIZE=FFH, fH=30k
Trapezoid Correction Amplitude8 VTRA8
VTRA5 , HSIZE=FFH, fH=150k
Trapezoid Correction Amplitude9 VTRA9
VTRA5 , HSIZE=FFH, fH-track=off
Weltrend Semiconductor, Inc.
Page 36
MIN
3.15
3.83
4.5
5.31
3.40
5.11
TYP MAX Unit
135 210 mV
135
210 mV
0
100 mV
0
100 mV
-135
-60 mV
-135
-60 mV
2.14
2.75 mV/step
TYP MAX Unit
3.5 3.85 V
4.25 4.68 V
5.0
5.5 V
5.91 6.51 mV/step
3.86 4.32 V
5.81 6.51 V
MIN
-350
TYP MAX Unit
-280 -210 mV
210
280
350 mV
-50
0
50 mV
-50
0
50 mV
210
280
350 mV
-350
-280
-210 mV
3.55
4.44
175
256
273
235
344
364
5.33 mV/ste
p
295 mV
432 mV
455 mV
WT9051
Data Sheet REV1.0
Side Pin Correction Block (measurement at pin5(EWO), (notice4, 6)
Parameter
Symbol Test Condition
Side Pin Correction Amplitude1
VSP1
SP=01H , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at top part,
fH-track=off
Side Pin Correction Amplitude2
VSP2
SP=01H , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at bottom part,
fH-track=off
Side Pin Correction Amplitude3
VSP3
SP=40H , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at top part,
fH-track=off
Side Pin Correction Amplitude4
VSP4
SP=40FH , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at bottom part,
fH-track=off
Side Pin Correction Amplitude5
VSP5
SP=7FH , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at top part,
fH-track=off
Side Pin Correction Amplitude6
VSP6
SP=7FH , VSIZE= FFH, HSIZE= FFH,
Difference from VEW3 at bottom part,
fH-track=off
Side Pin Correction Amplitude
VSP
V SP5- VSP1 /126
Amount
Side Pin Correction Amplitude7
VSP7
VSP5 , HSIZE=FFH, fH=30k
Side Pin Correction Amplitude8
VTSP8 VSP5 , HSIZE=FFH, fH=150k
Side Pin Correction Amplitude9
VSP9
VSP5 , HSIZE=FFH, fH-track=off
MIN
-120
TYP
0
MAX Unit
120 mV
-120
0
120 mV
430
725
1020 mV
430
725
1020 mV
1025
1450
1875 mV
1025
1450
1875 mV
9.21
11.51 13.81 mV/ste
p
844 1215 1586 mV
1237 1780 2323 mV
1320 1885 2451 mV
Side Pin Corner “Top” Correct Block (measurement at Pin5(EWO), (notice4, 5, 8)
Parameter
Symbol Test Condition
MIN
SPC-T Correction Amplitude1
VSPCT1 SPCT=00H , VSIZE= FFH, HSIZE= FFH, -480
Difference from VEW3 at top part,
fH-track=off
SPC-T Correction Amplitude2
VSPCT2 SPCT=00H , VSIZE= FFH, HSIZE= FFH, -80
Difference from VEW3 at bottom part,
fH-track=off
-80
SPC-T Correction Amplitude3
VSPCT3 SPCT =40H , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
-80
SPC-T Correction Amplitude4
VSPCT4 SPCT =40FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
200
SPC-T Correction Amplitude5
VSPCT5 SPCT =7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
-80
SPC-T Correction Amplitude6
VSPCT6 SPCT =7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
SPC-T Correction Amplitude
VSPCT
V SPCT5- VSPCT1 /127
3.17
Amount
SPC-T Correction Amplitude7
VSPCT7 VSPCT 5 , HSIZE=FFH, fH=30k
165
SPC-T Correction Amplitude8
VSPCT8 VSPCT 5 , HSIZE=FFH, fH=150k
242
SPC-T Correction Amplitude9
VSPCT9 VSPCT 5 , HSIZE=00H, fH-track=off
256
Weltrend Semiconductor, Inc.
Page 37
TYP
-340
MAX Unit
-200 mV
0
80
mV
0
80
mV
0
80
mV
340
0
5.40
285
417
442
480 mV
80
mV
7.62 mV/ste
p
405 mV
592 mV
628 mV
WT9051
Data Sheet REV1.0
Side Pin Corner “BOTTOM” Correct Block (measurement at Pin5(EWO), (notice4, 5, 8)
Parameter
Symbol Test Condition
MIN TYP
0
SPC-B Correction Amplitude1
VSPCB1 SPCB=00H , VSIZE= FFH, HSIZE= FFH, -80
Difference from VEW3 at top part,
fH-track=off
SPC-B Correction Amplitude2
VSPCB2 SPCB=00H , VSIZE= FFH, HSIZE= FFH, -480 -340
Difference from VEW3 at bottom part,
fH-track=off
-80
0
SPC-B Correction Amplitude3
VSPCB3 SPCB =40H , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
-80
0
SPC-B Correction Amplitude4
VSPCB4 SPCB =40FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
-80
0
SPC-B Correction Amplitude5
VSPCB5 SPCB =7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at top part,
fH-track=off
200
340
SPC-B Correction Amplitude6
VSPCB6 SPCB =7FH , VSIZE= FFH, HSIZE=
FFH, Difference from VEW3 at bottom
part, fH-track=off
SPC-B Correction Amplitude
VSPCB V SPCB6- VSPCB2 /127
3.17 5.40
Amount
SPC-B Correction Amplitude7
VSPCB7 VSPCB 6 , HSIZE=FFH, fH=30k
165
285
SPC-B Correction Amplitude8
VSPCB8 VSPCB6 , HSIZE=FFH, fH=150k
242
417
SPC-B Correction Amplitude9
VSPCB9 VSPCB6 , HSIZE=FFH, fH-track=off
256
442
Parallelogram Correction Block (internal measurement, (notice 10,11))
Parameter
Symbol Test Condition
Parallelogram Correction
VPARA1 PARA=01H , Top part
Amplitude1
Parallelogram Correction
VPARA2 PARA=01H , Bottom part
Amplitude2
Parallelogram Correction
VPARA3 PARA =40H , Top part
Amplitude3
Parallelogram Correction
VPARA4 PARA=40H , Bottom part
Amplitude4
Parallelogram Correction
VPARA5 PARA =7FH , Top part
Amplitude5
Parallelogram Correction
VPARA6 PARA=7FH , Bottom part
Amplitude6
Parallelogram Correction Amount VPARA T PARA5- TPARA1 /126
Weltrend Semiconductor, Inc.
Page 38
MAX Unit
80 mV
-200 mV
80
mV
80
mV
80
mV
480 mV
7.62 mV/ste
p
405 mV
592 mV
628 mV
MIN
-300
TYP
-240
MAX Unit
-180 mV
180
240
300 mV
-45
0
45
mV
-45
0
45
mV
180
240
300 mV
-300
-240
-180 mV
3.04
3.81
4.58 mV/step
WT9051
Data Sheet REV1.0
Side Pin Balance Correct Block (internal measurement, (notice9, 11))
Parameter
Symbol Test Condition
SPB Correction
VSPB1
SPB=01H , Top part
Amplitude1
SPB Correction
VSPB2
SPB=01H , Bottom part
Amplitude2
SPB Correction
VSPB3
SPB =40H , Top part
Amplitude3
SPB Correction
VSPB4
SPB=40H , Bottom part
Amplitude4
SPB Correction
VSPB5
SPB =7FH , Top part
Amplitude5
SPB Correction
VSPB6
SPB=7FH , Bottom part
Amplitude6
SPB Correction Amount VSPB
T PARA5- TPARA1 /126
MIN
-600
TYP
-460
MAX Unit
-320 mV
-600
-460
-320 mV
-120
0
120 mV
-120
0
120 mV
320
460
600 mV
320
460
600 mV
5.84
7.30
8.76 mV/step
Side Pin Corner Balance Top Correction Block(internal measurement, (notice9,10, 13))
Parameter
Symbol Test Condition
MIN TYP
SPCB-T Correction
VSPCBT1 SPCBT=00H , Top part
-410 -310
Amplitude1
SPCB-T Correction
VSPCBT2 SPCBT=00H , Bottom part
-80
0
Amplitude2
SPCB-T Correction
VSPCBT3 SPCBT =40H , Top part
-80
0
Amplitude3
SPCB-T Correction
VSPCBT4 SPCBT=40H , Bottom part
-80
0
Amplitude4
SPCB-T Correction
VSPCBT5 SPCBT =7FH , Top part
210
310
Amplitude5
SPCB-T Correction
Amplitude6
SPCB-T Correction
Amount
VSPCBT6
SPCBT=7FH , Bottom part
-80
0
VSPCBT
V SPCBT5- VSPCBT1 /127
3.33
4.92
MAX Unit
-210 mV
80
mV
80
mV
80
mV
410 mV
80
mV
6.51 mV/step
Side Pin Corner Balance Bottom Correction Block(internal measurement, (notice9,10, 12))
Parameter
Symbol Test Condition
MIN TYP MAX Unit
SPCB-B
Correction VSPCBB1 SPCBB=00H , Top part
-80
0
80 mV
Amplitude1
SPCB- B
VSPCBB2 SPCBB=00H , Bottom part
210
310
410 mV
Correction Amplitude2
SPCB- B
VSPCBB3 SPCBB =40H , Top part
-80
0
80 mV
Correction Amplitude3
SPCB- B
VSPCBB4 SPCBB=40H , Bottom part
-80
0
80 mV
Correction Amplitude4
SPCB- B
VSPCBB5 SPCBB =7FH , Top part
-80
0
80 mV
Correction Amplitude5
SPCB-B
Correction Amplitude6
SPCB- B
Correction Amount
VSPCBB6
SPCBB=7FH , Bottom part
-410
-310
-210 mV
VSPCBB
V SPCBB5- VSPCBB1 /127
3.33
4.92
6.51 mV/step
Weltrend Semiconductor, Inc.
Page 39
WT9051
Data Sheet REV1.0
<EHT Unit>
H-EHT Block(measurement at pin5(EW))
Parameter
Symbol Test Condition
7pinOpen Voltage
V7PIN
Input Minimum D-Range VLEHTH
Minimum input voltage
Input Maximum D-Range VHEHTH
Maximum input voltage
EHT-H Correction Gain1 GEHTH1
Between EWO to EHTH gain FH- tracking
=off
EHT-H Correction Gain2 GEHTH2
GEHTH1, fH=30k
EHT-H Correction Gain3 GEHTH3
GEHTH1, fH=150k
V-EHT Block (measurement at pin4(VSAWO))
Parameter
Symbol Test Condition
6pinOpen Voltage
V6PIN
Input Minimum D-Range VLEHTV
Minimum input voltage
Input Maximum D-Range VHEHTV
Maximum input voltage
EHT-V Correction Gain1 GEHTV1
Between Vsawo to EHTV gain Vsize=FF
EHT-V Correction Gain2 GEHTV2
Between Vsawo to EHTV gain Vsize=01
MIN
3.6
4.77
-1.06
TYP
4.0
-0.88
MAX
4.4
2.2
-0.70
Unit
V
V
V
Times
-0.28
-1.70
-0.20
-1.42
-0.12
-1.14
Times
Times
MIN
3.6
4.75
1.47
1.65
TYP
4.0
1.72
1.92
MAX
4.4
3.81
1.97
2.19
Unit
V
V
V
Times
Times
MIN
0
TYP
2.8
MAX
5.0
Unit
ppm
170
200
230
ppm
1.32
1.55
1.79
ppm
MIN
0
3.06
24.09
TYP
0.4
3.6
28.35
MAX
0.8
4.14
32.60
Unit
mVp-p
mVp-p
uV/step
MIN
0.3
1.5
8.7
1.8
1.05
0.3
1.5
8.7
0.25
0.70
3.6
TYP
0.5
2.0
11.9
2.41
1.4
0.5
2.0
11.9
0.36
1.00
5.1
MAX
0.7
2.5
15.3
3.01
1.75
0.7
2.5
15.3
0.47
1.30
6.6
Unit
Vp-p
Vp-p
mV/step
Vp-p
Vp-p
Vp-p
Vp-p
mV/step
us
us
ns/step
<Moire Canceller Unit>
Horizontal Moire Canceller Block(measurement at 17pin(HOUT))
Parameter
Symbol Test Condition
H Moire Canceller Variable1 THMC1 HMC=01H, fH=30kHz
Ratio with period
H Moire Canceller Variable2 THMC2 HMC=7FH, fH=30kHz
Ratio with period
H Moire Canceller Variable THMC
THMC2- THMC1 /126
Amount
Vertical Moire Canceller Block (measurement at 4 pin(VSAWO))
Parameter
Symbol Test Condition
V Moire Canceller Variable1 VVMC1 VMC=01H
V Moire Canceller Variable2 VVMC2 VMC=7FH
V Moire Canceller Variable VVMC
VVMC2- VVMC1 /126
Amount
<Dynamic Focus Unit>
Horizontal/Vertical Mixed Dynamic Focus Block (measurement at 8pin)
Parameter
Symbol Test Condition
H-DF Amplitude1
VHDFMA1 HDFA=01HEX, 04HEXD7=”1”
H-DF Amplitude2
VHDFMA2 HDFA=7FHEX, 04HEXD7=”1”
H-DF Amplitude Amount
VHDFMA VHDFMA2- VHDFMA1 /126
H-DF Amplitude3
VHDFMA3 VHDFMA2, HSIZE-Track=ON HSIZE=00HEX
H-DF Amplitude4
VHDFMA4 VHDFMA2, HSIZE-Track=ON HSIZE=FFHEX
V-DF Amplitude1
VVDFMA1 VDFA=01HEX, 04HEXD7=”1”
V-DF Amplitude2
VVDFMA2 VDFA=01HEX, 04HEXD7=”1”
V-DF Amplitude Amount
VVDFMA VVDFA2- VVDFM1 /126
H-DF Phase1
VHDFP1 HDFP=00 HEX
H-DF Phase2
VHDFP2 HDFP=7F HEX
H-DF Phase Amount
VHDFP VHDFP2- VHDFP1 /127
Weltrend Semiconductor, Inc.
Page 40
WT9051
Data Sheet REV1.0
Vertical Dynamic Focus Block (measurement at 9pin)
Parameter
Symbol Test Condition
V-DF Amplitude1
VVDFA1 VDFA=01HEX, DFSelect=”0”
V-DF Amplitude2
VVDFA2 VDFA=7FHEX, DFSelect=”0”
V-DF Amplitude Amount
VVDFA VVDFA2- VVDFA1 /126
MIN
0.6
3.0
18
TYP
1.0
4.0
24
MAX
1.4
5.0
30
Unit
Vp-p
Vp-p
mV/step
MIN
0
TYP
0
MAX
0
Unit
V
4.5
5.0
5.5
V
2.25
2.5
2.75
V
4.5
5.0
5.5
V
PWM OSC Block (measurement at pin13)
Parameter
Symbol Test Condition
Low level
VL
Input 5V at pin11
MIN
0.8
TYP
1.0
MAX
1.2
Unit
V
PWM OUT Block(measurement at pin14)
Parameter
Symbol Test Condition
PWM Duty1
PD1
fH=30kHz, V12=1V
PWM Duty2
PD2
fH=30kHz, V12=2V
PWM Duty3
PD1
fH=30kHz, V12=3V
PWM Duty4
PD4
fH=30kHz, V12=4V
PWM Duty5
PD5
fH=30kHz, V12=5V
PWM Duty1
PD1
fH=90kHz, V12=1V
PWM Duty2
PD2
fH=90kHz, V12=2V
PWM Duty3
PD3
fH=90kHz, V12=3V
PWM Duty4
PD4
fH=90kHz, V12=4V
PWM Duty1
PD1
fH=150kHz, V12=1V
PWM Duty2
PD2
fH=150kHz, V12=2V
PWM Duty3
PD3
fH=150kHz, V12=3V
MIN
94
88
81
73
65
93
74
53
30
91
60
25
TYP
99
93
86
78
70
98
79
58
35
96
65
30
MAX
100
98
91
83
75
100
84
63
40
100
70
35
Unit
%
%
%
%
%
%
%
%
%
%
%
%
MIN
4.8
TYP
5.0
MAX
5.2
Unit
V
<PWM Unit>
Error AMP Block (measurement at pin12)
Parameter
Symbol Test Condition
Input Low Voltage
VEINL
Input VEIN at pin11, short between pin11and
pin12
Input High Voltage
VEINH input VEIN at pin11, short between pin11
and pin12
Reference Voltage
VREF
No signal at pin11, short between pin11 and
pin12
Limit level
VLIM
Input 6V at pin11, short between pin11 and
pin12
<X-RAY Det. Units>
X-RAY Det. Block (measurement at pin19)
Parameter
Symbol Test Condition
Threshold Voltage
VXRAY
Weltrend Semiconductor, Inc.
Page 41
WT9051
Data Sheet REV1.0
Notice:
1.The period is the time, which excluded retrace width of V-SAW from the vertical period.
2.The Vertical C Correction is off mode.
3.The Vertical S Correction is off mode.
4.The Trapezoid Correction is off mode.
5.The Side Pin Correction is off mode.
6.The Side Pin Corner Top/Bottom Correction is off mode.
7.The Side Pin Corner Top Correction is center.
8.The Side Pin Corner Bottom Correction is center.
9.The Parallelogram Correction is off mode.
10.The Side Pin Balance Correction is off mode.
11.The Side Pin Corner Balance Top/Bottom Correction is off mode.
12.The Side Pin Corner Balance Top Correction is center.
13.The Side Pin Corner Balance Bottom Correction is center.
14.The precision of the D/A converter is as follows.
8bits DAC ： --1LSB ∼ +2LSB
7bits DAC ： --1LSB ∼ +1.5LSB
ORDERING INFORMATION
Part Number
WT9051
Package
30-pin plastic shrink DIP (400 mil)
Weltrend Semiconductor, Inc.
Page 42