Elantec EL4583CS Sync separator, 50% slice, s-h, filter, hout Datasheet

Sync Separator, 50% Slice, S-H, Filter, HOUT
Features
General Description
• NTSC, PAL, and SECAM sync
separation
• Single supply, +5V operation
• Precision 50% slicing
• Built-in programmable color burst
filter
• Decodes non-standard vertical
• Horizontal sync output
• Sync. pulse amplitude output
• Same socket can be used for 8-pin
EL4581C
• Low-power CMOS
• Detects loss of signal
• Resistor programmable scan rate
• Few external components
• Available in 16-pin PDIP and 16pin SO (0.150”) packages
The EL4583C extracts timing from video sync in NTSC, PAL, and
SECAM systems, and non standard formats, or from computer graphics operating at higher scan rates. Timing adjustment is via an external
resistor. Input without valid vertical interval (no serration pulses) produces a default vertical output.
Applications
The level output pin provides a signal with twice the sync amplitude
which may be used to control an external AGC function. A
TTL/CMOS compatible No Signal Detect Output flags a loss or reduction in input signal level. A resistor sets the Set Detect Level.
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•
•
•
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Video special effects
Video test equipment
Video distribution
Multimedia
Displays
Imaging
Video data capture
Video triggers
Outputs are: composite sync, vertical sync, filter, burst/back porch,
horizontal, no signal detect, level, and odd/even output (in interlaced
scan formats only).
The EL4583C sync slice level is set to the mid-point between sync tip
and the blanking level. This 50% point is determined by two internal
sample and hold circuits that track sync tip and back porch levels. It
provides hum and noise rejection and compensates for input levels of
0.5V to 2.0VP-P.
A built in filter attenuates the chroma signal to prevent color burst
from disturbing the 50% sync slice. Cut off frequency is set by a resistor to ground from the Filter Cut Off pin. Additionally, the filter can be
by-passed and video signal fed directly to the Video Input.
The EL4583C is manufactured using Elantec’s high performance analog CMOS process.
Connection Diagram
FILTER CUT OFF 1
Ordering Information
SET DETECT LEVEL 2
COMPOSITE SYNC OUT 3
Package
Tape &
Reel
Outline #
EL4583CN
16-Pin PDIP
-
MDP0031
EL4583CS
16-Pin SO (0.150”)
-
MDP0027
EL4583CS-T7
16-Pin SO (0.150”)
7”
MDP0027
EL4583CS-T13
16-Pin SO (0.150”)
13”
MDP0027
Part No
FILTER INPUT 4
VERTICAL SYNC OUT 5
DIGITAL GND 6
COMPOSITE VIDEO INPUT 8
16 ANALOG GND
15 HORIZONTAL SYNC OUT
14 VDD
13 ODD/EVEN OUTPUT
12 RSET*
11 BURST/BACK PORCH OUTPUT
10 NO SIGNAL DETECT OUTPUT
9 LEVEL OUTPUT
EL4583C
(8-Pin SO & 8-Pin PDIP)
*Note: RSET must be a 1% register
Manufactured under US Patent 5,528,303
Note: All information contained in this data sheet has been carefully checked and is believed to be accurate as of the date of publication; however, this data sheet cannot be a “controlled document”. Current revisions, if any, to these
specifications are maintained at the factory and are available upon your request. We recommend checking the revision level before finalization of your design documentation.
August 6, 2001
FILTER OUTPUT 7
© 2001 Elantec Semiconductor, Inc.
EL4583C
EL4583C
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
Absolute Maximum Ratings (T
VCC Supply
Storage Temperature
Pin Voltages
A
= 25°C)
7V
-65°C to +150°C
-0.5V to VCC +0.5V
Operating Temperature Range
Power Dissipation
Die Junction Temperature
-40°C to +85°C
See Curves
150°C
Important Note:
All parameters having Min/Max specifications are guaranteed. Typ values are for information purposes only. Unless otherwise noted, all tests are at the
specified temperature and are pulsed tests, therefore: TJ = TC = TA.
DC Electrical Characteristics
VDD = 5V, TA = 25°C, R SET = 681kΩ, RF = 22kΩ, RLV = 82kΩ
Parameter
Description
IDD
VDD = 5V [1]
Clamp Voltage
Pins 4, 8, unloaded
Discharge Current
Pins 4, 8, with Signal (VIN = 2V)
Discharge Current
Pins 4, 8, no Signal [2]
Clamp Charge Current
Pins 4, 8, VIN = 1V
Ref. Voltage VREF
Min
Typ
Max
Unit
2.5
4
mA
1.3
1.55
1.8
V
3
6
12
µA
4
mA
V
10
µA
2
3
Pin 12, VDD = 5V [3]
1.5
1.75
2
Filter Reference Voltage, VRF
Pin 1
0.35
0.5
0.65
V
Level Reference Current
Pin 2 [4]
1.5
2.5
3.5
µA
VOL Output Low Voltage
IOL = 1.6mA
350
800
mV
VOH Output High Voltage
1.
2.
3.
4.
IOH = -40µA
4
IOH = -1.6mA
2.4
No video signal, outputs unloaded
At loss of signal (pin 10 high) the pull down current source switches to a value of 10µA
Tested for V DD 5V ±5%
Current sourced from pin 2 is VREF/RSET
2
4
V
Dynamic Characteristics
RF = 22kΩ, RSET = 681kΩ, V DD = 5V, Video Input = 1VP-P, TA = 25°C, C L = 15pF, IOH = -1.6mA, IOL = 1.6mA
Parameter
Description
Horizontal Pulse Width, Pin 15, tH
[1]
Vertical Sync Width, Pin 5, tVS
[2]
Burst/Back Porch Width, Pin 11, tB
[1]
Filter Attenuation
Min
Typ
Max
Unit
3.8
5
6.2
µs
195
2.7
FIN = 3.6MHz [3]
3.7
µs
4.7
12
Comp. Sync Prop. Delay, tCS
VIN (Pin 4)—Comp Sync
Input Dynamic Range
p-p NTSC Signal
0.4
Input Voltage = 1Vp-p
40
50
60
VSLICE/VBLANK
40
50
60
500
600
700
27
36
57
µs
400
600
800
µs
250
400
ns
Slice Level
Level Out, Pin 9
Input Voltage = 1Vp-p, Pin 4
Vertical Sync Default Time, tVSD
[4]
Loss of Signal Time-Out
Pin 10
Burst/Back Porch Delay, tBD
See Figure 4
1.
2.
3.
4.
250
µs
dB
Width is a function of RSET
c/s, Vertical, Back porch and H are all active low, V OH = 0.8V; vertical is 3H lines wide of NTSC signal
Attenuation is a function of RF. See filter typical characteristics
Vertical pulse width in absence of serrations on input signal
3
400
ns
2
V
%
mV
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
Pin Descriptions
Pin No.
Pin Name
1
Filter Cut-Off
2
Set Detect Level
Function
A resistor RF connected between this input and ground determines the input filter characteristic. Increasing RF
increases the filter 3.58MHz color burst attenuation. See the typical performance characteristics.
A resistor RLV connected between pin 2 and ground determines the value of the minimum signal which triggers the
loss of signal output on pin 10. The relationship is V PMIN = 0.75RLV/RSET, where VPMIN is the minimum detected
sync pulse amplitude applied to pin 4. See the typical performance characteristics.
3
Composite Sync Output
4
Filter Input
This output replicates all the sync inputs on the input video.
The filter is a 3 pole active filter with a gain of 2, designed to produce a constant phase delay of nominally 260ns with
signal amplitude. Resistor RF on pin 1 controls the filter cut-off. An internal clamp sets the minimum voltage on pin
4 at 1.55V when the input becomes low impedance. Above the clamp voltage, an input current of 1µA charges the
input coupling capacitor. With loss of signal, the current source switches to a value of 10µA, for faster signal recovery.
5
Vertical Sync Output
The vertical sync output is synchronous with the first serration pulse rising edge in the vertical interval of the input
signal and ends on the trailing edge of the first equalizing Output pulse after the vertical interval. It will therefore be
slightly more than 3H lines wide.
6
Digital Ground
7
Filter Output
Output of the active 3 pole filter which has its input on pin 4. It is recommended to ac couple the output to pin 8.
8
Video Input
This input can be directly driven by the signal if it is desired to bypass the filter, for example, in the case of strong
clean signals. This input is 6dB less sensitive than the filter input.
9
Level Output
This pin provides an analog voltage which is nominally equal to twice the sync pulse amplitude of the video input signal applied to pin 4. It therefore provides an indication of signal strength.
10
No Signal Detect Output
This is a digital output which goes high when either a) loss of input signal or b) the input signal level falls below a predetermined amplitude as set by RLV on pin 2. There will be several horizontal lines delay before the output is
initiated.
11
Burst/Back Porch Output
The start of back porch output is triggered on the trailing edge of normal H sync, and on the rising edge of serration
pulses in the vertical interval. The pulse is timed out internally to produce a one-shot output. The pulse width is a function of RSET. This output can be used for d.c. restore functions where the back porch level is a known reference.
12
RSET
The current through the resistor RSET determines the timing of the functions within the I.C. These functions include
the sampling of the sync pulse 50% point, back porch output and the 2H eliminator. For faster scan rates, the resistor
needs to be reduced inversely. For NTSC 15.7kHz scan rate RSET is 681k 1%. RSET must be a 1% resistor.
13
Odd/Even Output
Odd-even output is low for even field and high for odd field. The operation of this circuit has been improved for rejecting spurious noise pulses such as those present in VCR signals.
14
VDD 5V
15
Horizontal Sync Output
16
Analog Ground
This is the ground return for digital buffer outputs.
The internal circuits are designed to have a high immunity to supply variations, although as with most I.C.s a 0.1µF
decoupling capacitor is advisable.
This output produces only true H pulses of nominal width 5µs. The leading edge is triggered from the leading edge of
the input H sync, with the same prop. delay as the composite sync. The half line pulses present in the input signal during vertical blanking are eliminated with an internal 2H eliminator circuit.
This is the ground return for the signal paths in the chips, RSET, RF and RLV.
4
Typical Performance Curves
RSET vs
Horizontal Frequency
Back Porch Clamp
On Time vs RSET
Vertical Default Delay
Time vs RSET
Filter 3dB BW vs RF
Level Out (Pin 9) vs
Sync. Tip Amplitude
Minimum Signal Detect
vs RLV
Filter Attenuation vs RF @
f = 3.58MHz
1.8
Package Power Dissipation vs Ambient Temp.
JEDEC JESD51-3 Low Effective Thermal Conductivity Test Board
1.54W
1.6
θJ
Power Dissipation (W)
1.4
1.2 1.136W
A=
PD
IP
81
°
C/
16
W
1
θJ
0.8
A =1
0.6
SO
16
10
°C/
W
0.4
0.2
0
0
25
50
75 85
100
125
Ambient Temperature (°C)
Note 1: For RLV < 1000k¾, no signal detect output (pin 10) will default high at minimum signal sensitivity specification, or at complete loss of signal.
5
150
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
Timing Diagram
Notes:
b. The composite sync output reproduces all the video input sync pulses, with a propagation delay.
c. Vertical sync leading edge is coincident with the first vertical serration pulse leading edge, with a propagation delay.
d. Odd-even output is low for even field, and high for odd field.
e. Back porch goes low for a fixed pulse width on the trailing edge of video input sync pulses. Note that for serration pulses during vertical, the back porch starts on the rising edge
of the serration pulse (with propagation delay).
f. Horizontal sync output produces the true “H” pulses of nominal width of 5µs. It has the same delay as the composite sync.
Figure 1.
6
Figure 2.
Figure 3.
7
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
Figure 4. Standard (NTSC Input) H. Sync Detail
8
Description of Operation
A simplified block schematic is shown in Figure 1. The
following description is intended to provide the user
with sufficient information to understand the effects of
the external components and signal conditions on the
outputs of the integrated circuit.
chip. Reference VR4 with op-amp A2 forces pin 12 to a
reference voltage of 1.7V nominal. Consequently, it can
be seen that the external resistance RSET will determine
the value of the reference current ITR. The internal resistance R3 is only about 6kΩ, much less than RSET. All
the internal timing functions on the chip are referenced
to ITR and have excellent supply voltage rejection.
The video signal is AC coupled to pin 4 via the capacitor
C1, nominally 0.1µF. The clamp circuit A1 will prevent
the input signal on pin 4 going more negative than 1.5V,
the value of reference voltage V R1. Thus the sync tip, the
most negative part of the video waveform, will be
clamped at 1.5V. The current source I1, nominally 6µA,
charges the coupling capacitor during the remaining portion of the H line, approximately 58µs for a 15.75kHz
timebase. From I • t = C • V, the video time-constant can
be calculated. It is important to note that the charge
taken from the capacitor during video must be replaced
during the sync tip time, which is much shorter, (ratio of
x 12.5). The corresponding current to restore the charge
during sync will therefore be an order of magnitude
higher, and any resistance in series with CI will cause
sync tip crushing. For this reason, the internal series
resistance has been minimized and external high resistance values in series with the input coupling capacitor
should be avoided. The user can exercise some control
over the value of the input time constant by introducing
an external pull-up resistance from pin 4 to the 5V supply. The maximum voltage across the resistance will be
VDD less 1.5V, for black level. For a net discharge current greater than zero, the resistance should be greater
than 450k. This will have the effect of increasing the
time constant and reducing the degree of picture tilt. The
current source I1 directly tracks reference current ITR
and thus increases with scan rate adjustment, as
explained later.
To improve noise immunity, the output of the 3 pole filter is brought out to pin 7. It is recommended to AC
couple the output to pin 8, the video input pin. In case of
strong clean video signal, the video input pin, pin 8, can
be driven by the signal directly.
Comparator C2 on the input to the sample and hold
block (S/H) compares the leading and trailing edges of
the sync. pulse with a threshold voltage VR2 which is
referenced at a fixed level above the clamp voltage VR1.
The output of C2 initiates the timing one-shots for gating
the sample and hold circuits. The sample of the sync tip
is delayed by 0.8µs to enable the actual sample of 2µs to
be taken on the optimum section of the sync. pulse tip.
The acquisition time of the circuit is about three horizontal lines. The double poly CMOS technology enables
long time constants to be achieved with small high quality on-chip capacitors. The back porch voltage is
similarly derived from the trailing edge of sync, which
also serves to cut off the tip sample if the gate time
exceeds the tip period. Note that the sample and hold
gating times will track RSET through IOT.
The 50% level of the sync tip is derived through the
resistor divider R1 and R2, from the sample and held
voltages VTIP and VBP and applied to the plus input of
comparator C1. This comparator has built in hysteresis
to avoid false triggering. The output of C2 is a digital 5V
signal which feeds the C/S output buffer B1, the vertical,
back porch and odd/even functions.
The signal is processed through an active 3 pole filter
(F1) designed for minimum ripple with constant phase
delay. The filter attenuates the color burst by 12dB and
eliminates fast transient spikes without sync crushing.
An external filter is not necessary. The filter also amplifies the video signal by 6dB to improve the detection
accuracy. The filter cut-off frequency is controlled by an
external resistor from pin 1 to ground.
The vertical circuit senses C/S edges and initiates an
integrator which is reset by the shorter horizontal sync
pulses but times out with the longer vertical sync. pulse
widths. The internal timing circuits are referenced to IOT
and VR3, the timout period being inversely proportional
to the timing current. The vertical output pulse is started
on the first serration pulse in the vertical interval and is
Internal reference voltages (block VREF ) with high
immunity to supply voltage variation are derived on the
9
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
then self-timed out. In the absence of a serration pulse,
an internal timer will default the start of vertical.
The Horizontal circuit senses C/S edges and produces
the true horizontal pulses of nominal width 5µs. The
leading edge is triggered from the leading edge of the
input H sync, with the same prop. delay as composite
sync. The half line pulses present in the input signal during vertical blanking are removed with an internal 2H
eliminator circuit. The 2H eliminator initiates a time out
period after a horizontal pulse is generated. The time out
period is a function of IOT which is set by RSET.
The back porch is triggered from the sync tip trailing
edge and initiates a one-shot pulse. The period of this
pulse is again a function of IOT and will therefore track
the scan rate set by RESET.
The odd/even circuit (O/E) tracks the relationship of the
horizontal pulses to the leading edge of the vertical output and will switch on every field at the start of vertical.
Pin 13 is high during an odd field.
Loss of video signal can be detected by monitoring the
No Signal Detect Output pin 10. The VTIP voltage held
by the sample and hold is compared with a voltage level
set by RLV on pin 2. Pin 10 output goes high when the
VTIP falls below RLV set value.
VTIP voltage is also passed through an amplifier with
gain of 2 and buffed to pin 9. This provides an indication
of signal strength. This signal (Level Output) can be
used for AGC applications.
10
Block Diagram
* Note: RSET must be a 1% resistor
Figure 5. Standard (NTSC Input) H. Sync Detail
11
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
EL4583C
EL4583C
Sync Separator, 50% Slice, S-H, Filter, HOUT
General Disclaimer
Specifications contained in this data sheet are in effect as of the publication date shown. Elantec, Inc. reserves the right to make changes in the circuitry or specifications contained herein at any time without notice. Elantec, Inc. assumes no responsibility for the use of any circuits described
herein and makes no representations that they are free from patent infringement.
August 6, 2001
WARNING - Life Support Policy
Elantec, Inc. products are not authorized for and should not be used
within Life Support Systems without the specific written consent of
Elantec, Inc. Life Support systems are equipment intended to support or sustain life and whose failure to perform when properly used
in accordance with instructions provided can be reasonably
expected to result in significant personal injury or death. Users contemplating application of Elantec, Inc. Products in Life Support
Systems are requested to contact Elantec, Inc. factory headquarters
to establish suitable terms & conditions for these applications. Elantec, Inc.’s warranty is limited to replacement of defective
components and does not cover injury to persons or property or
other consequential damages.
Elantec Semiconductor, Inc.
675 Trade Zone Blvd.
Milpitas, CA 95035
Telephone: (408) 945-1323
(888) ELANTEC
Fax:
(408) 945-9305
European Office: +44-118-977-6020
Japan Technical Center: +81-45-682-5820
12
Printed in U.S.A.
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