NSC LM1296N

LM1296
Raster Geometry Correction System for Multi-Frequency
Displays
General Description
The LM1296 is a monolithic IC for use in the raster scanning
circuitry of a multi-frequency CRT monitor. The IC provides
an S-corrected sawtooth waveform and a variable DC output
voltage. These two outputs drive the vertical deflection amplifier. It also provides another waveform for East-West geometry correction which includes pincushion, corner, and
trapezoid controls. The geometry correction is controlled by
DC input voltages from 0V to 4V.
The raster height and the raster vertical position can be controlled by two DC voltage input pins that adjust the sawtooth
waveform amplitude and the variable DC output voltage. The
East-West correction of the LM1296 has height tracking and
vertical position tracking capabilities. As the height or position of the raster is adjusted the geometry correction is maintained by the chip automatically.
The LM1296 is packaged in a 16-pin plastic DIP package.
Accepts either polarity of V sync
DC-controlled correction terms
Raster vertical position control
Vertical S-correction (linearity) control
East-West pincushion control
East-West trapezoid control
East-West corner control
Provides both polarities of correction output
East-West correction tracks raster vertical position and
height
n Compatible with LM1290 and LM1292 horizontal PLL
n
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Applications
n Vertical deflection of monitors
Features
n Vertical scanning frequency 50 Hz–165 Hz
Connection Diagram
DS012894-1
FIGURE 1.
Order Number LM1296N
See NS Package Number N16A
© 1998 National Semiconductor Corporation
DS012894
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LM1296 Raster Geometry Correction System for Multi-Frequency Displays
February 1998
Absolute Maximum Ratings (Notes 3, 1)
ESD Susceptibility (Note 5)
Storage Temperature
Lead Temperature (Soldering 10 sec.)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage (VCC)
Input Voltage (VIN)
Pins 1, 2, 8, 9, 10, 16
Power Dissipation (PD)
Above 25˚C, Derate
Based on θJA and TJ (Note 4)
Thermal Resistance (θJA)
Junction Temperature (TJMAX)
2 kV
−65˚C to +150˚C
265˚C
Operating Ratings(Note 2)
15V
10.8V ≤ VCC ≤ 13.2V
Supply Voltage (VCC)
Input Voltage (VIN)
Pins 1, 2, 8, 9, 10, 16
Output Current (IOUT)
Pins 11, 13, 15
Temperature Range (TA)
0V ≤ VIN ≤ 5V
1.5W
81˚C/W
150˚C
0V ≤ VIN ≤ 4V
−2 mA ≤ IOUT ≤ 2 mA
0˚C to +70˚C
Electrical Characteristics
See Test Circuit (Figure 2), VCC = 12V; V2 = 4V; V16 = 4V; VRDCV = 0V (Note 6); TA = 25˚C unless otherwise specified
Symbol
Parameter
Conditions
ICC
Supply Current
Pins 11, 13, 15 Loaded, 2mA
V SYNC
Vertical Sync Input Sensitivity (Pin 7)
1% or 99% Duty Cycle
Min
Typ
Max
(Note 8)
(Note 7)
(Note 8)
26
32
Rectangular Waveform
1
Units
mA
VPP
AC-Coupled to Pin 7
fMIN
Minimum Lock Frequency
fMAX
Maximum Lock Frequency
fFR
Free Run Frequency
RIN1
Input Resistance (Pin 1)
Through 0.01 µF Cap.
COSC = 0.15 µF
COSC = 0.15 µF
V7 = 4V or 0V
V2 = 1V
50
165
Hz
Hz
40
Hz
25
kΩ
12
kΩ
RIN2
Input Resistance (Pin 2)
RIN3
Input Resistance (Pins 8, 9, 10)
50
kΩ
RIN4
Input Resistance (Pin 16)
50
kΩ
VO15
SAWTOOTH OUT (Pin 15)
Output Amplitude (RL15 = 5 kΩ)
V2 = 4V, V16
V2 = 4V, V16
V2 = 0V, V16
V2 = 0V, V16
= 0V
= 4V
1.8
= 0V
= 4V
1
3.1
VPP
1.7
VDC15
SAWTOOTH OUT (Pin 15)
Output DC Voltage (RL15 = 5 kΩ)
V2 = 0V to 4V, V16 = 0V to 4V
3.9
V
kTEMP
SAWTOOTH OUT (Pin 15)
(Note 9)
1.5
%
V2 = 4V, V16 = 4V
V2 = 4V, V16 = 0V
V1 = 4V
V1 = 1.5V
0.5
%
Temperature Stability
kS
VRDCV
S-Correction of Sawtooth Output (Pin 15)
Relative DC Voltage between
DC OUT (Pin 13) and
2
−200
mV
200
SAWTOOTH OUT (Pin 15)
VRDCV = V13 − VDC15
(RL13 = 5 kΩ)
VTRAP
VPIN
Trapezoid Correction
V2 = 4V, V8 = 0V
V2 = 4V, V8 = 4V
0.87
Output Waveform Amplitude
(Pin 11, RL11 = 5 kΩ)
Pincushion and Corner
Pincushion Correction
Corrections are Null
V2 = 4V, V10 = 0V
1.9
V2 = 4V, V10 = 4V
1.45
Output Waveform Amplitude
(Pin 11, RL11 = 5 kΩ)
Trapezoid and Corner
Corrections are Null
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2
VPP
0.73
VPP
Electrical Characteristics
(Continued)
See Test Circuit (Figure 2), VCC = 12V; V2 = 4V; V16 = 4V; VRDCV = 0V (Note 6); TA = 25˚C unless otherwise specified
Symbol
VCNR
Parameter
Corner Correction
Output Waveform Amplitude
(Pin 11, RL11 = 5 kΩ)
Conditions
V2 = 4V, V9 = 0V
V2 = 4V, V9 = 4V
Min
Typ
Max
(Note 8)
(Note 7)
(Note 8)
1.1
Units
VPP
0.8
Trapezoid and Pincushion
Corrections are Null
VDC11
E-W OUT
Trapezoid, Pincushion, and
Output Offset Voltage
(Pin 11, RL11 = 5 kΩ)
Corner Correction Waveforms
4.1
V
are Null
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur.
Note 2: Operating Ratings indicate conditions for which the device is functional, but do not guarantee specific performance limits. For guaranteed specifications and
test conditions, see the Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test conditions.
Note 3: All voltages are measured with respect to GND, unless otherwise specified.
Note 4: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, θJA and the ambient temperature, TA. The maximum
allowable power dissipation at any elevated temperature is PD = (TJMAX – TA)/θJA or the number given in the Absolute Maximum Ratings, whichever is lower. For
this device, TJMAX = 150˚C. The typical thermal resistance (θJA) of the LM1296 is 81˚C/W.
Note 5: Human Body model, 100 pF capacitor discharged through a 1.5 kΩ resistor.
Note 6: Adjust V1 until VRDCV = 0V, where VRDCV = V13 − VDC15.
Note 7: Typical specifications are specified at TA = 25˚C and represent most likely parametric norm.
Note 8: Tested limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 9: Amplitude stability versus ambient temperature is defined by |V70 − V25|/V25 x 100%, where V70 and V25 are the output sawtooth peak-to-peak amplitudes
at 70˚C and 25˚C respectively.
Test Circuit
DS012894-2
FIGURE 2.
Typical Performance Characteristics
TA = 25˚C, fv = 60 Hz, V2 = 4V, V16 = 4V, VRDCV = 0V, V8,9,10 = Set for null correction waveforms, unless otherwise specified
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Typical Performance Characteristics
(Continued)
E-W Out (Pin 11)
E-W Out (Pin 11)
DS012894-3
DS012894-4
E-W Out (Pin 11)
E-W Out (Pin 11)
DS012894-5
DS012894-6
E-W Out (Pin 11)
E-W Out (Pin 11)
DS012894-7
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DS012894-8
4
Block Diagram
DS012894-9
FIGURE 3.
Functional Description
Referring to Figure 4, the extent of S correction is defined by
the following equation.
kS = (∆A1 + ∆A2)/2A x 100%
The LM1296 outputs a sawtooth and a variable DC voltage
for the vertical deflection amplifier. It also provides the horizontal deflection output circuit with a waveform for Trapezoid, Pincushion and Corner correction.
Referring to Figure 3, pin 7 (V SYNC) goes to the Sync Polarity Correction Block that accepts either positive-going or
negative-going sync signals. The polarity-corrected sync is
sent to the Injection-Locked Oscillator so that the sawtooth
generated is synchronized with the vertical sync. With no
sync signal AC-coupled to pin 7, the oscillator free runs at
typically 40 Hz.
There are three capacitors and one control pin connected to
the Sawtooth Waveform Generation Block. COSC is the timing capacitor for the Injection-Locked Oscillator. CF is the filter capacitor for an internal circuit that detects the existence
of vertical sync and prevents the Injection-Locked Oscillator
from locking at twice the vertical sync frequency. CALC is for
the automatic level control (ALC) circuit. The ALC circuit
maintains the sawtooth output amplitude, which is set by the
DC voltage at pin 2 (HEIGHT), regardless of the vertical sync
frequency. Since the output sawtooth goes to the geometry
correction circuit as well, the correction waveform generated
tracks the sawtooth amplitude, i.e., the height of the CRT
raster.
The S Correction block shapes the linear sawtooth into an
S-shape sawtooth. Pin 15 (SAWTOOTH OUT) outputs the
buffered S-shape sawtooth. The amount of S correction is
controlled by the DC voltage at pin 16 (S).
DS012894-10
FIGURE 4.
The LM1296 is designed to drive an external vertical deflection amplifier that is operating with positive and negative
power supplies. The LM1296 outputs an S-corrected sawtooth with a DC level that is typical 3.85V. Pin 13 (DC OUT)
provides a DC voltage of 3.85V ± 200 mV. By applying a DC
control voltage to pin 1 (POSITION), the output voltage at pin
13 can be varied. This sets the output DC current from the
vertical deflection amplifier, which in turn sets the raster vertical position.
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Functional Description
(Continued)
Pin 1 (POSITION) not only controls the pin 13 output, but
also the center position of the correction waveform at pin 11
(E-W OUT). As a result, the geometry correction tracks the
vertical position of the CRT raster. See Figure 5 through Figure 7.
The Pincushion Control Block and the Corner Control Block
are non-linear analog circuits. They convert the sawtooth
waveform into 2nd order and 4th order parabolic waveforms.
These two parabolic waveforms, together with a sawtooth
(1st order), are summed and then buffered out at pin 11
(E-W OUT). See waveforms in the Typical Performance
Characteristics section. The amplitudes of the 1st, 2nd and
4th order components in the correction waveform are controlled by the DC voltages at pin 8 (TRAPEZOID), pin 9
(CORNER) and pin 10 (PINCUSHION).
DS012894-12
FIGURE 6. Raster Position Up
DS012894-13
FIGURE 7. Raster Position Down
DS012894-11
FIGURE 5. Raster Position Centered
Pin Descriptions
See Figure 8 through Figure 13 for input and output schematics.
Pin 1. POSITION: A 0V to 4V DC voltage applied to this pin
sets pin 13 (DC OUT) output voltage from 3.65V to 4.05V.
See Figure 8 for the input schematic.
Pin 2. HEIGHT: A 0V to 4V DC voltage applied to this pin
sets the output amplitude of the sawtooth waveform at pin 15
(SAWTOOTH OUT) as well as the output amplitude of the
correction waveform at pin 11 (E-W OUT). See Figure 9 for
the input schematic.
Pin 3. CF: A 0.47 µF capacitor is connected from this pin to
ground. This capacitor prevents the Injection-Locked Oscillator from locking at twice the V sync frequency.
Pin 4. CALC: A filter capacitor for the automatic level control
circuit (ALC) is connected from this pin to ground. The ALC
circuit maintains the output amplitudes of SAWTOOTH OUT
and E-W OUT regardless of the V sync frequency. The recommended capacitance of CALC is between 1 µF to 4.7 µF.
Pin 5. COSC: A timing capacitor for the Injection-Locked Oscillator is connected from this pin to ground. The recommended capacitance is 0.15 µF. Increasing the capacitance
will lower the lowest lock frequency.
varied depending on the application and the ambient noise
level inside the monitor. A DC voltage of 0V or 4V on this pin
will cause the device to free run at about 40 Hz.
Pin 8. TRAPEZOID: A 0V to 4V DC voltage applied to this
pin adjusts the polarity and the amount of linear sawtooth
component (Trapezoid Correction) in the E-W OUT output.
At approximately 2V, the amount is zero. A voltage above 2V
sets a negative-sloped sawtooth output, increasing the voltage increases the sawtooth amplitude. A voltage below 2V
sets a positive-sloped sawtooth output, decreasing the voltage increases the sawtooth amplitude. See Figure 11 for the
input schematic.
Pin 9. CORNER: A 0V to 4V DC voltage applied to this pin
adjusts the polarity and the amount of 4th order parabolic
component (Corner Correction) in the E-W OUT output. At
approximately 2V, the amount is zero. A voltage above 2V
sets a concave down 4th order output, increasing the voltage
increases the 4th order amplitude. A voltage below 2V sets a
concave up 4th order output, decreasing the voltage increases the 4th order amplitude. See Figure 11 for the input
schematic.
Pin 10. PINCUSHION: A 0V to 4V DC voltage applied to this
pin adjusts the polarity and the amount of 2nd order parabolic component (Puncushion Correction) in the E-W OUT
output. At approximately 2V, the amount is zero. A voltage
above 2V sets a concave down 2nd order output, increasing
the voltage increases the 2nd order amplitude. A voltage below 2V sets a concave up 2nd order output, decreasing the
voltage increases the 2nd order amplitude. See Figure 11 for
the input schematic.
Pin 6. GND: Ground pin.
Pin 7. V SYNC: This pin accepts AC-coupled V sync of either polarity. See Figure 10 for the input schematic. The input
sensitivity of this pin is about 1 VPP. For best noise immunity,
a resistor of 10 kΩ in parallel with a filter capacitor of 0.01 µF
should be connected from the input side of the coupling capacitor to ground. The values of these components may be
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Pin Descriptions
Pin 14. VCC: 12V nominal power supply pin. This pin should
be decoupled to pin 6 (GND) via a short path with a capacitor
of at least 100 µF.
(Continued)
Pin 11. E-W OUT: The output waveform at this pin consists
of the sum of the linear sawtooth, 2nd order parabolic and
4th order parabolic waveform components. The center position of the output waveform tracks the output voltage at pin
13 (DC OUT). See Figure 12 for the output schematic.
Pin 12. CBP: A capacitor of at least 100 µF is connected from
this pin to ground via a short path.
Pin 13. DC OUT: This pin outputs a variable DC voltage from
3.65V to 4.05V. The output voltage is controlled by the control voltage at pin 1 (POSITION). See Figure 12 for the output schematic.
Pin 15. SAWTOOTH OUT: This pin outputs an S-corrected
sawtooth waveform with the amplitude controlled by pin 2
(HEIGHT). See Figure 12 for the output schematic.
Pin 16: S: A 0V to 4V DC voltage applied to this pin adjusts
the amount of S correction in the sawtooth waveform at pin
15 (SAWTOOTH OUT). 0V sets maximum S correction. See
Figure 13 for the input schematic.
Input/Output Schematics
DS012894-17
DS012894-14
FIGURE 11.
FIGURE 8.
DS012894-15
FIGURE 9.
DS012894-18
FIGURE 12.
DS012894-19
DS012894-16
FIGURE 13.
FIGURE 10.
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* Actual values depend on the application and the ambient noise level inside the monitor.
DS012894-20
Typical Application
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9
LM1296 Raster Geometry Correction System for Multi-Frequency Displays
Physical Dimensions
inches (millimeters) unless otherwise noted
16-Lead (0.300" Wide) Molded Dual-In-Line Package
Order Number LM1296N
NS Package Number N16A
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