MICRO-LINEAR ML6427

August 1999
PRELIMINARY
ML6427
75W Quad Video Cable Drivers and Filters
with Switchable Inputs
GENERAL DESCRIPTION
FEATURES
The ML6427 is a quad 4th-order Butterworth lowpass
reconstruction filter plus quad video amplifier optimized
for minimum overshoot and flat group delay. Each filter
channel has a two-input multiplexer that switches between
two groups of quad video signals. Applications driving
SCART and EVC cables are supported for composite,
component, and RGB video.
■
Cable drivers for Peritel (SCART), Enhanced Video
Connector (EVC), and standard video connectors, 75W
cable drivers for CV, S-video, and RGB
■
7.1MHz CV, RGB, and S-video, NTSC or PAL filters
with mux inputs and output channel mux
■
Quad reconstruction filter or dual anti-aliasing filter
■
43dB stopband attenuation at 27MHz
■
1dB flatness up to 4.8MHz
A fifth unfiltered channel is provided to support an
additional analog composite video input. A swapping
multiplexer between the two composite channels allows
the distribution amplifiers to output from either input.
■
12ns group delay flatness up to 10MHz
■
0.4% differential gain, 0.4º differential phase on all
channels
Several ML6427s can be arranged in a master-slave
configuration where an external sync can be used for CV
and RGB outputs.
■
0.4% total harmonic distortion on all channels
■
Master-slave configuration allows up to 8 multiplexed,
filtered output signals
1VP-P input signals from DACs are AC coupled into the
ML6427 where they are DC restored. Outputs are AC
coupled and drive 2VP-P into a 150W load. The ML6427
can provide DC coupled outputs for certain applications.
BLOCK DIAGRAM
17
VCCORGB
UNFILTERED CHANNEL
SYNCIN
2
3
4
7
8
9
TRANSCONDUCTANCE
ERROR AMP
TRANSCONDUCTANCE
ERROR AMP
BINA/C1
11
BINB/C2
12
A/B MUX
×2
CVOUT1/YOUTA
21
4th-ORDER
FILTER
×2
CVOUT/YOUTB
20
4th-ORDER
FILTER
×2
ROUT/YOUTC
18
4th-ORDER
FILTER
×2
GOUT/YOUTD
16
4th-ORDER
FILTER
×2
BOUT/COUT
15
0.5V
+
–
0.5V
MUX
TRANSCONDUCTANCE
ERROR AMP
+
–
MUX
TRANSCONDUCTANCE
ERROR AMP
0.5V
+
–
MUX
13
SWAP CVF
SWAP
MUX
REQUIRED
SYNC STRIP
GINA/Y6
GINB/Y2
10
1
MUX
14
SWAP CVU
+
–
RINA/Y4
RINB/Y5
6
VCC
SYNC
TIMER
CVINFA/Y2*
CVINFB/Y3*
TRANSCONDUCTANCE
ERROR AMP
SYNC
TIMER
SYNCIN
23
SYNCOUT
24
22
VCCOCV
0.5V
+
–
*CAN ALSO INPUT SYNC ON GREEN SIGNALS
0.75V
GNDO
19
GND
5
1
ML6427
PIN CONFIGURATION
ML6427
24-Pin SOIC (S24)
A/B MUX
1
24
SYNCOUT
CVINU/Y1
2
23
SYNCIN
CVINFA/Y2
3
22
VCCOCV
CVINFB/Y3
4
21
CVOUT1/YOUTA
GND
5
20
CVOUT2/YOUTB
VCC
6
19
GNDO
RINA/Y4
7
18
ROUT/YOUTC
RINB/Y5
8
17
VCCORGB
GINA/Y6
9
16
GOUT/YOUTD
GINB/Y7
10
15
BOUT/COUT
BINA/C1
11
14
SWAP CVU
BINB/C2
12
13
SWAP CVF
TOP VIEW
2
ML6427
PIN DESCRIPTION
PIN
NAME
1
A/B MUX
2
3
4
CVINU/Y1
CVINFA/Y2
CVINFB/Y3
FUNCTION
PIN
Logic input pin to select between
Bank <A> or <B> of the CV, RGB,
or Y/C inputs. Internally pulled high.
12 BINB/C2
Filtered analog BLUE video or
chroma video input for Bank <B>
13 SWAP CVF
Logic input pin to select whether
the outputs of CVOUT1/YOUTA and
CVOUT2/YOUTB are from filtered or
unfiltered CV sources. See Table 1.
Internally pulled low.
14 SWAP CVU
Logic input pin to select whether
the outputs of CVOUT1/YOUTA and
CVOUT2/YOUTB are from filtered or
unfiltered CV sources. See Table 1.
Internally pulled low.
15 BOUT/COUT
Analog BLUE video output or
chroma output from either BINA/C1
or BINB/C2
16 GOUT/YOUTD
Analog GREEN video output or
luma output from either GINA/Y6 or
GINB/Y7
17 VCCORGB
5V power supply for output buffers
of the RGB drivers
18 ROUT/YOUTC
Analog RED video output or luma
output from either RINA/Y4 or RINB/
Y5
19 GNDO
Ground for output buffers
Unfiltered analog composite video
or luma video input. Internally
pulled high. A composite or luma or
green signal must be present on
either the CVINFA/Y2 or the CVINFB/
Y3 input to provide necessary sync
signals to other channels (R, G, B, Y,
C). Otherwise, sync must be
provided at SYNCIN. For RGB
applications the green channel with
sync can be used as an input to this
pin (see RGB Applications section).
Filtered analog composite video or
luma video input for Bank <A>.
Note that SYNC is stripped from this
signal for the other channels. A
composite or luma or green signal
must be present on either the
CVINFA/Y2 or the CVINFB/Y3 input
to provide necessary sync signals to
other channels (R, G, B, Y, C).
Otherwise, sync must be provided
at SYNCIN. For RGB applications
the green channel with sync can be
used as an input to this pin (see
RGB Applications section).
Filtered analog composite video or
luma video input for Bank <B>.
Note that SYNC is stripped from this
signal for the other channels.
5
GND
Analog ground
6
VCC
Analog 5V supply
7
RINA/Y4
Filtered analog RED video or luma
video input for Bank <A>
8
RINB / Y5
Filtered analog RED video or luma
video input for Bank <B>
9
GINA/Y6
Filtered analog GREEN video or
luma video input for Bank <A>
10 GINB/Y7
Filtered analog GREEN video or
luma video input for Bank <B>
11 BINA/C1
Filtered analog BLUE video or
chroma video input for Bank <A>
NAME
FUNCTION
20 CVOUT2/YOUTB Composite video output for channel
2 or luma output.
21 CVOUT1/YOUTA Composite video output for channel
1 or luma output.
22 VCCOCV
5V power supply for output buffers
of the CV drivers.
23 SYNCIN
Input for an external H-sync logic
signal for filtered channels. TTL or
CMOS. For normal operation
SYNCOUT is connected to
SYNCIN.
24 SYNCOUT
Logic output for H-sync detect for
CVINFA/Y2 or CVINFB/Y3. TTL or
CMOS. For normal operation
SYNCOUT is connected to
SYNCIN.
3
ML6427
ABSOLUTE MAXIMUM RATINGS
Storage Temperature Range...................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec) ..................... 260°C
Thermal Resistance (qJA) ...................................... 80°C/W
Absolute maximum ratings are those values beyond which
the device could be permanently damaged. Absolute
maximum ratings are stress ratings only and functional
device operation is not implied.
OPERATING CONDITIONS
VCC .................................................................................................. 6V
Junction Temperature ............................................. 150°C
ESD ..................................................................... >2000V
Temperature Range ........................................ 0°C to 70°C
VDD Range ................................................... 4.5V to 5.5V
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC = 5V ±10%, TA = Operating Temperature Range (Note 1)
SYMBOL
PARAMETER
CONDITIONS
ICC
Supply Current
No Load (VCC = 5V)
AV
Low Frequency Gain (All Channels)
VIN = 100mVP-P at 300kHz
VSYNC
TYP
MAX
90
UNITS
mA
5.34
6.0
6.65
dB
Channel Sync Output Level CV/Y, R/Y, G/Y Sync Present and Clamp Settled
0.6
0.9
1.1
V
B/C
Sync Present and Clamp Settled
1.2
1.4
1.5
V
Unfiltered
Sync Present and Clamp Settled
0.7
1.0
1.2
V
tCLAMP
Clamp Response Time
Settled to Within 10mV, CIN=0.1µF
10
ms
f0.5dB
0.5dB Bandwidth
(Flatness. All Filtered Channels)
All Outputs
4.5
MHz
fC
–3dB Bandwidth
(Flatness. All Filtered Channels)
All Outputs (With no Peaking Cap.
See Figures 2 and 13)
7.1
MHz
0.8 x fC Attenuation, All Filtered Channels
All Outputs
1.5
dB
fSB
Stopband Rejection
All Filtered Channels
fIN = 27MHz to 100MHz worst case
(See Figures 2 and 13)
–35
–41
dB
Vi
Input Signal Dynamic Range (All Channels) AC Coupled
1
1.25
VP-P
1
mVRMS
4.3
%
120
mA
0.8fC
NOISE
6.7
Output Noise (All Channels)
Over a Frequency Band
of 25Hz-50MHz
OS
Peak Overshoot (All Channels)
2VP-P Output Pulse
ISC
Output Short Circuit Current (All Channels) Note 2
CL
Output Load Capacitance (All Channels)
Load at the Output Pin
dG
Differential Gain (All Channels)
All Outputs
0.4
%
dF
Differential Phase (All Channels)
All Outputs
0.4
º
THD
Output Distortion (All Channels)
VOUT = 1.8VP-P at 3.58/4.43MHz
0.4
%
Crosstalk
Input of 0.5VP-P at 3.58/4.43MHz
on any channel to output of any
other channel
–55
dB
Input of 0.5VP-P at 3.58/4.43MHz
–54
dB
Input of 0.5VP-P at 3.58/4.43MHz
–52
dB
XTALK
Input A/B MUX Crosstalk
Swap Mux Crosstalk
4
MIN
35
pF
ML6427
ELECTRICAL CHARACTERISTICS (Continued)
SYMBOL
PSRR
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
PSRR (All Channels)
0.5VP-P (100kHz) at VCC
–39
dB
Group Delay (All Channels)
at 100kHz
60
ns
Group Delay Deviation from Flatness
to 3.58MHz (NTSC)
4
ns
to 4.43MHz (PAL)
7
ns
(All Channels)
to 10MHz
12
ns
VIH
Input Voltage Logic High
A/B MUX, SWAP CVU, SWAP CVF
VIL
Input Voltage Logic Low
A/B MUX, SWAP CVU, SWAP CVF
tpd
Dtpd
Note 1:
Limits are guaranteed by 100% testing, sampling, or correlation with worst case test conditions.
Note 2:
Sustained short circuit protection limited to 10 seconds.
2.5
V
1
V
5
ML6427
FUNCTIONAL DESCRIPTION
The ML6427 is a quad monolithic continuous time analog
video filter designed for reconstructing signals from four
video D/A sources. The ML6427 is intended for use in AC
coupled input and output applications.
of the “slave” ML6427 it will have its SYNCIN input
connected to the SYNCOUT output of the “master”
ML6427.
SYNCIN AND SYNCOUT PINS
The filters approximate a 4th-order Butterworth
characteristic with an optimization toward low overshoot
and flat group delay. All outputs are capable of driving
2VP-P into AC coupled 150W video loads with up to 35pF
of load capacitance at the output pin. They are also
capable of driving a 75W load at 1VP-P.
All channels are clamped during sync to establish the
appropriate output voltage swing range. Consequently the
input coupling capacitors do not behave according to the
conventional RC time constant. Clamping for all channels
settles within 10ms of a change in video sources.
Input coupling capacitors of 0.1µF are recommended for
all channels. During sync a feedback error amplifier
sources/sinks current to restore the DC level. The net result
is that the average input current is zero. Any change in the
value of the input coupling capacitors will linearly affect
the clamp response times.
The RGB channels have no pulldown current sources and
are essentially tilt-free. The inputs of the CV channels sink
less than 1µA during active video, resulting in a tilt of less
than 1mV for 220µF output capacitors. A 1000µF
capacitor is recommended for TV applications to minimize
tilt in the CV channels.
SWAP MULTIPLEXER CONTROL
Output pins CVOUT1/YOUTA and CVOUT2/YOUTB are each
independently selectable among three input sources
(CVINU/Y1, CVINFA/Y2, or CVINFB/Y3) depending on the
state of digital inputs SWAP CVF, SWAP CVU, and A/B
MUX. This allows the two outputs to remain independent
and pass straight through, or to remain independent but
swapped, or for both outputs to have the same signal
sourcing from either CVINU/Y1, CVINFA/Y2, or CVINFB/Y3
(See Table 1). If SWAP CVF is forced to logic low then
CVOUT2/YOUTB is sourced from either the CVINFA/Y2 OR
THE CVINFB/Y3 input. If SWAP CVU is logic low then
CVOUT1/YOUTA provides video from either the CVINFA/Y2
OR THE CVINFB/Y3 input. If SWAP CVF is logic high then
CVOUT2/YOUTB provides video from the CVINU/Y1 input.
If SWAP CVU is high then CVOUT1/YOUTA provides video
from either the CVINFA/Y2 or the CVINFB/Y3 input. Both
SWAP CVF and SWAP CVU will pull low if they are not
driven.
The ML6427 is robust and stable under all stated load and
input conditions. Bypassing both VCC pins directly to
ground ensures this performance. Two ML6427s can be
connected in a master-slave sync configuration. When
using this configuration (See Figure 6) only the “master”
ML6427 is required to have a signal with embedded sync
present on the CVINFA/Y2 and CVINFB/Y3 inputs. In the
absence of sync on the CVINFA/Y2 and CVINFB/Y3 inputs
6
Each ML6427 has two sync detectors which control the
DC restore functions. The unfiltered channel has its own
detector, which controls the DC restore function during
the horizontal sync period of the CVINU/Y1 input. The
other sync detector controls the DC restore functions for
the filtered channels based upon the composite or luma
silgnal at the CVINFA/Y2 or CVINFB/Y3 input.
Required Setup: A composite or luma or green signal
must be present on CVINFA/Y2 or CVINFB/Y3 inputs to
provide necessary sync signals to other channels (R, G, B,
Y, C). Otherwise, sync must be provided at the SYNCIN
pin. For RGB applications the green channel with sync can
be used as an input to CVINFA/Y2 or CVINFB/Y3.
The SYNCOUT pin provides a logic high when it detects
the horizontal sync of either the CVINFA/Y2 or CVINFB/Y3
input (note that one input is selected by the A/B MUX pin).
The SYNCIN pin is an input for an external H-sync logic
signal to enable or disable the internal DC restore loop for
the filtered channels. When SYNCIN is logic high the DC
restore function is enabled.
For normal operation the SYNCOUT pin is connected to
the SYNCIN pin (see Figure 4). If neither the CVINFA/Y2
nor the CVINFB/Y3 has an embedded sync an external
sync can be applied on the SYNCIN pin. In master-slave
configurations the SYNCOUT of a ML6427 master can be
used as the SYNCIN of a ML6427 slave (see Figure 6).
VIDEO I/O DESCRIPTION
Each input is driven by either a low impedance source or
the output of a 75W terminated line. The input is required
to be AC coupled via a 0.1µF coupling capacitor which
gives a nominal clamping time of 10ms. All outputs are
capable of driving an AC coupled 150W load at 2VP-P or
1VP-P into a 75W load. At the output pin, up to 35pF of
load capacitance can be driven without stability or slew
issues. A 220µF AC coupling capacitor is recommended at
the output to reduce power consumption. For DC coupled
outputs see the Typical Applications section.
ANALOG MULTIPLEXER CONTROL
The four filter channels each have two input multiplexers
which are paired to select between two four-channel
video sources (i.e., composite video plus RGB component
video). If A/B MUX is forced to logic high, it will select
Bank<A> of the video inputs (CVINFA/Y2, RINA/Y4, GINA/
Y6, BINA/C1) to be enabled. If A/B MUX is logic low then
Bank<B> of video inputs (CVINFB/Y3, RINB/Y5,GINB/Y7,
BINFB/C2) will be selected. If the A/B MUX is open it will
pull to logic high.
1
20
0
0
AMPLITUDE (dB)
AMPLITUDE (dB)
ML6427
–1
–2
–3
–4
–20
–40
–60
0
0.1
1
–80
0.01
10
0.1
FREQUENCY (MHz)
1
10
100
FREQUENCY (MHz)
Figure 1. Passband Flatness (Normalized)
All outputs. Passband is ripple-free.
Figure 2. Passband/Stopband Rejection Ratios
(Normalized) All outputs.
90
DELAY (ns)
70
50
30
10
1
2
3
4
5
6
7
8
9
10
11
FREQUENCY (MHz)
Figure 3. Group Delay, all Outputs
Low frequency group delay is 62ns. At 3.58MHz group
delay increases by only 4ns. At 4.43MHz group delay
increases by only 7ns. The maximum deviation from flat
group delay of 12ns occurs at 6MHz.
A/B MUX
INPUTS
SWAP CVU
SWAP CVF
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
CVOUT1/YOUTA CVOUT2/YOUTB
CVINU/Y1
CVINU/Y1
CVINFB/Y3
CVINFB/Y3
CVINU/Y1
CVINU/Y1
CVINFA/Y2
CVINFA/Y2
CVINFB/Y3
CVINU/Y1
CVINFB/Y3
CVINU/Y1
CVINFA/Y2
CVINU/Y1
CVINFA/Y2
CVINU/Y1
OUTPUTS
ROUT/YOUTC
GOUT/YOUTD
BOUT/COUT
RINB/Y5
RINB/Y5
RINB/Y5
RINB/Y5
RINA/Y4
RINA/Y4
RINA/Y4
RINA/Y4
GINB/Y7
GINB/Y7
GINB/Y7
GINB/Y7
GINA/Y6
GINA/Y6
GINA/Y6
GINA/Y6
BINB/C2
BINB/C2
BINB/C2
BINB/C2
BINA/C1
BINA/C1
BINA/C1
BINA/C1
Table 1. Selecting Composite, Luma, RGB, and Chroma Outputs
7
ML6427
TYPICAL APPLICATIONS
BASIC APPLICATIONS
OSD (ON-SCREEN DISPLAY) APPLICATIONS
The ML6427 provides channels for two banks of inputs for
RGB and composite video. The R and G channels can be
used as luma inputs while the B channel can be used as a
chroma input. Composite outputs and an H-sync output
are also provided. There are several configurations
available with the ML6427. Figure 4 includes a list of
basic output options for composite, S-video, TV modulator,
and RGB outputs. Note that each composite channel can
drive a CV load and a channel modulator simultaneously.
The ML6427 standalone can be used as an EVC or SCART
cable driver with nine video sources (75W or low
impedance buffer) and seven video outputs. All inputs and
outputs are AC coupled. When driving seven loads the
power dissipation must be calculated to ensure that the
junction temperature doesn't exceed 120ºC.
Unfiltered RGB video from an OSD processor needs to be
filtered and then synchronized to a fast blanking interval
or alpha-key signal for later video processing. With the
total filter delay being 80ns ±10ns a D flip-flop or similar
delay element can be used to delay the fast blanking
interval or alpha-key signal. This will synchronize the RGB
and OSD signals (Figure 9).
CCIR656 AND CCIR601 APPLICATIONS
Composite or luma channels can be fed back into an
alternate channel or into another ML6427 (master-slave
configuration) so that approximately 80dB/decade
attenuation outputs are provided. The ML6427 can be
configured for composite and luma loopback (Figure 7).
H-sync outputs are also provided.
EVC CABLE DRIVING
CHANNEL MULTIPLEXING
The ML6427 can be configured to drive composite video,
S-video, and horizontal sync through an EVC connector
(Figure 5). Composite video and S-video inputs are filtered
through 4th-order Butterworth filters and driven through
internal 75W cable drivers. A buffered H-sync output is
also available.
The ML6427 can be configured for multiple composite
channel multiplexing (Figure 8). Composite sources such
as VCRs, video game consoles, and camcorders can be
selected using the ML6427 swap mux controls. A/B MUX,
SWAP CVU, and SWAP CVF signals can be used to select
and route from various input sources.
SCART CABLE DRIVING
DC COUPLED APPLICATIONS
The ML6427 can be configured either as a SCART cable
driver (Figure 4) or as a SCART cable driver and S-video
driver (Figure 6). A horizontal sync output is also available.
Note that the ML6427 can be used in a master-slave mode
where the SYNCOUT signal from the master is used as the
SYNCIN signal of the slave. This allows the CV, S-video,
and RGB channels to operate under the same sync signals.
Note that in SCART applications it is not always necessary
to AC couple the outputs. Systems using SCART
connectors for RGB and composite video can typically
handle between 0 and 2VDC offset (see DC Coupled
Applications section).
RGB APPLICATIONS
RGB video can be filtered and driven through the ML6427
in one of two ways:
1. For sync suppressed RGB the sync signal can be derived
from the composite or luma signal on the inputs of
CVINFA/Y2 or CVINFB/Y3.
2. For RGB with sync on the green signal the green
channel must be fed into either the CVINFA/Y2 or CVINFB/
Y3 input. The sync will be extracted from green and used
on red and bue channels. See also the SYNCIN and
SYNCOUT Sections.
8
A 220µF capacitor coupled with a 150W termination
resistor forms a highpass filter which blocks DC while
passing the video frequencies and avoiding tilt. Lower
value capacitors, such as 10µF, would create a problem.
By AC coupling the average DC level is zero.
Consequently the output voltages of all channels will be
centered around zero.
Alternately, DC coupling the output of the ML6427 is
allowable. There are several tradeoffs: The average DC
level on the outputs will be 2V; Each output will dissipate
an additional 40mW nominally; The application will need
to accommodate a 1VDC offset sync tip; and it is
recommended to use only one 75W load per output.
However, if it is necessary to drive two loads at a time on
the composite output while DC coupling is used then the
swap–mux and 5th line driver can be configured to enable
the filtered composite signal on both the 4th and 5th line
drivers. This divides the composite load driving
requirement into two line drivers versus one.
Required Setup: A composite or luma or green signal must
be present on the CVINFA/Y2 or the CVINFB/Y3 input to
provide necessary sync signals to the other channels (R, G,
B, Y, C). Otherwise, sync must be provided at the SYNCIN
pin. For RGB applications, the green channel with sync
can be used as an input to CVINFA/Y2 or CVINFB/Y3.
ML6427
TYPICAL APPLICATIONS (Continued)
USING THE ML6427 FOR PAL APPLICATIONS
capacitors (220pF, 270pF, 330pF and none) between 0 and
10MHz.
The ML6427 can be optimized for PAL video by adding
frequency peaking to the composite and S-video outputs.
Figure 10 illustrates the use of an additional external
capacitor (330pF) in parallel with the output source
termination resistor. This raises the frequency response
from 1.6dB at 4.8MHz to 0.35dB at 4.8MHz, which
allows for accurate reproduction of the upper sideband of
the PAL subcarrier. Figure 11 shows the frequency
response of PAL video with various values of peaking
19
GNDO
CVINU/Y1
2
5
GND
17
VCCORGB
22
VCCOCV
6
VCC
220µF
CVOUT1/YOUTA
CVINFA/Y2
3
For NTSC applications without the peaking capacitor the
rejection at 27MHz is 42dB (typical). For PAL applications
with the peaking capacitor the rejection at 27MHz is 38dB
(typical). See Figure 12. The differential group delay,
shown in Figure 13 with and without a peaking capacitor
(220pF, 270pF, and 330pF and none), varies slightly with
capacitance from 8ns to 13ns.
VIDEO CABLES
75Ω
CV/Y
21
MODULATOR
CVINFB/Y3
4
220µF
RINA/Y4
7
CVOUT2/YOUTB
RINB/Y5
8
10
11
12
ROUT/YOUTC
GINB/Y7
BINA/C1
GOUT/YOUTD
BINB/C2
BOUT/COUT
SYNCIN
23
CV/Y
20
MODULATOR
ML6427
GINA/Y6
9
75Ω
SYNCOUT
24
A/B MUX
1
220µF
75Ω
R/Y
18
220µF
75Ω
220µF
75Ω
G/Y
16
B/C
15
SWAP CVF SWAP CVU
13
14
OPTIONAL FOR DC COUPLED APPLICATIONS
H SYNC OUT
INPUTS
Bank A:
Bank B:
Other:
OUTPUTS
RGB, CV filtered path
RGB, CV filtered path
CV unfiltered path, Sync IN (slave mode)
Option 1: 2 CV outputs + 2 TV modulator outputs, 1 RGB output
Option 2: 2 CV outputs + 1 TV modulator output, 1 S-video output
Other:
Sync output (buffered stripped sync)
Figure 4. Basic Application for NTSC
2
COMPOSITE
VIDEO IN
3
4
LUMA IN
7
8
9
10
CHROMA IN
11
12
19
GNDO
CVINU/Y1
5
GND
17
VCCORGB
22
VCCOCV
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
21
CVINFB/Y3
COMPOSITE
VIDEO OUT
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
ML6427
MASTER
GINA/Y6
GINB/Y7
ROUT/YOUTC
BINA/C1
GOUT/YOUTD
BINB/C2
BOUT/COUT
SYNCIN
23
SYNCOUT
24
A/B MUX
1
20
18
LUMA
OUT
S-VIDEO
OUT
16
15
TO EVC
CONNECTOR
CHROMA
OUT
SWAP CVF SWAP CVU
13
14
H SYNC OUT
Figure 5. EVC (Enhanced Video Connector) Application: S-Video, Composite, plus H-Sync out
9
ML6427
19
GNDO
2
COMPOSITE
VIDEO IN
3
4
LUMA IN
7
8
9
10
CHROMA IN
11
12
5
GND
17
VCCORGB
22
VCCOCV
CVINU/Y1
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
21
COMPOSITE
VIDEO OUT
CVINFB/Y3
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
20
ML6427
MASTER
GINA/Y6
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BOUT/COUT
BINB/C2
SYNCIN
23
SYNCOUT
24
A/B MUX
1
18
LUMA
OUT
S-VIDEO
OUT
16
15
CHROMA
OUT
SWAP CVF SWAP CVU
13
14
H SYNC OUT
24
SYNC OUT
2
3
4
R INPUT
7
8
RGB INPUT
G INPUT
9
10
B INPUT
11
12
23
SYNC IN
17
VCCORGB
CVINU/Y1
22
VCCOCV
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
21
CVINFB/Y3
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
20
ML6427
SLAVE
GINA/Y6
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BOUT/COUT
BINB/C2
GNDO
19
GND
5
A/B MUX
1
18
R OUTPUT
16
G OUTPUT
15
B OUTPUT
RGB
VIDEO
OUT
SWAP CVF SWAP CVU
13
14
Figure 6. SCART (Peritel) + S-Video Application: S-Video, RGB, Composite, plus H-Sync out
10
TO SCART
CONNECTOR
ML6427
1kΩ
19
GNDO
2
COMPOSITE
VIDEO IN
CV0
3
4
7
1kΩ
8
9
LUMA IN
10
CHROMA IN
11
12
5
GND
17
VCCORGB
22
VCCOCV
CVINU/Y1
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
21
CVINFB/Y3
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
20
CVL
ML6427
MASTER
GINA/Y6
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BOUT/COUT
BINB/C2
SYNCIN
23
SYNCOUT
24
A/B MUX
1
18
16
15
CV+
(80dB/DECADE ATTENUATION)
COMPOSITE
VIDEO OUT
LUMA OUT
S-VIDEO
OUT
CHROMA OUT
SWAP CVF SWAP CVU
13
14
H SYNC OUT
Figure 7a. Composite Loopback (Cascaded Filters) for Additional Attenuation
1kΩ
19
GNDO
2
COMPOSITE
VIDEO IN
3
4
7
Y0
LUMA IN
8
9
1kΩ
10
CHROMA IN
11
12
5
GND
17
VCCORGB
CVINU/Y1
22
VCCOCV
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
21
CVINFB/Y3
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
20
ML6427
MASTER
COMPOSITE
VIDEO OUT
GINA/Y6
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BOUT/COUT
BINB/C2
SYNCIN
23
SYNCOUT
24
A/B MUX
1
18
16
15
YL
Y+
(80dB/DECADE ATTENUATION)
CHROMA OUT
S-VIDEO
OUT
SWAP CVF SWAP CVU
13
14
H SYNC OUT
Figure 7b. Luma Loopback (Cascaded Filters) for Additional Attenuation
Figure 7. CCIR656 and CCIR601 Application: Composite and Luma Loopback, plus H-Sync out
11
ML6427
VIDEO PLAYER
VIDEO RECORDER
MODULATOR
0.1µF
19
GNDO
CV1
2
CV2
COMPOSITE VIDEO IN
3
CV3
4
0.1µF
7
VIDEO GAME
CONSOLE
8
9
0.1µF
10
CAMCORDER
11
12
5
GND
17
VCCORGB
CVINU/Y1
22
VCCOCV
6
VCC
220µF
CVOUT1/YOUTA
CVINFA/Y2
21
CV OUTPUT 1
CVINFB/Y3
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
20
COMPOSITE VIDEO OUT
ML6427
MASTER
220µF
GINA/Y6
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BOUT/COUT
BINB/C2
SYNCIN
23
SYNCOUT
24
A/B MUX
INPUTS
SWAP CVU
SWAP CVF
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
A/B MUX
1
18
16
MODULATOR
TV
15
SWAP CVF SWAP CVU
13
14
OUTPUTS
CVOUT1/YOUTA
CVOUT2/YOUTB
Video Player
Video Player
Camcorder
Camcorder
Video Player
Video Player
Video Game Console
Video Game Console
Camcorder
Video Player
Camcorder
Video Player
Video Game Console
Video Player
Video Game Console
Video Player
Figure 8. Composite Channel Swapping Application: Multiple Composite Channel Multiplexing
12
ML6427
80ns±10ns DELAY
UNFILTERED
FILTERED
R
OSD
(ON-SCREEN DISPLAY)
PROCESSOR
G
B
ROUTPUT
ML6427
SCART/QUAD VIDEO
FILTER AND DRIVER
FAST BLANKING INTERVAL
OR ALPHA-KEY SIGNAL
D
GOUTPUT
BOUTPUT
TO MUX OR
OTHER
PROCESSING
FAST BLANKING
INTERVAL
OR ALPHA-KEY
SIGNAL
Q
13.5MHz/
27MHz
ML6431
GENLOCK/CLOCK
GENERATOR
DELAY AT 13.5MHz IS APPROXIMATELY 74ns
Figure 9. Synchronizing the Filter Delay with Fast Blanking or Alpha-Key Signals in OSD Applications
2
3
4
7
8
9
10
11
12
19
GNDO
CVINU/Y1
5
GND
17
VCCORGB
22
VCCOCV
6
VCC
CVOUT1/YOUTA
CVINFA/Y2
220µF
75Ω
VIDEO CABLES
CV/Y
21
330pF
MODULATOR
CVINFB/Y3
220µF
RINA/Y4
CVOUT2/YOUTB
RINB/Y5
ROUT/YOUTC
GINB/Y7
GOUT/YOUTD
BINA/C1
BINB/C2
SYNCIN
23
CV/Y
20
330pF
ML6427
GINA/Y6
BOUT/COUT
SYNCOUT
24
A/B MUX
1
75Ω
220µF
MODULATOR
75Ω
R/Y
18
220µF
75Ω
220µF
75Ω
G/Y
16
B/C
15
SWAP CVF SWAP CVU
13
14
OPTIONAL FOR DC COUPLED APPLICATIONS
H SYNC OUT
INPUTS
Bank A:
Bank B:
Other:
OUTPUTS
RGB, CV filtered path
RGB, CV filtered path
CV unfiltered path, Sync IN (slave mode)
Option 1: 2 CV outputs + 2 TV modulator outputs, 1 RGB output
Option 2: 2 CV outputs + 1 TV modulator output, 1 S-video output
Other:
Sync output (buffered stripped sync)
Figure 10. Basic Application for PAL
13
ML6427
–0.5
0.35dB
WITH
PEAKING
AMPLITUDE (dB)
0
0.5
1.7dB
WITHOUT
PEAKING
1
1.5
330pF
270pF
2
220pF
none
2.5
0
2
1
4
3
6
5
8
7
FREQUENCY (MHz)
Figure 11. NTSC/PAL Video Frequency Response With and Without Peaking Capacitor
0
AMPLITUDE (dB)
10
NTSC/PAL
–38dB
WITH
PEAKING
20
30
NTSC/PAL
–42dB
WITHOUT
PEAKING
330pF
40
270pF
220pF
none
50
0
3
6
9
12
15
18
21
24
27
30
FREQUENCY (MHz)
Figure 12. Stopband Rejection at 27MHz With and Without Peaking Capacitor
10
8ns
GROUP
DELAY
WITHOUT
PEAKING
DELAY (ns)
0
13ns GROUP
DELAY
WITH 330pF
PEAKING
–10
330pF
270pF
220pF
none
–20
0
1
2
3
4
5
6
7
8
9
10
FREQUENCY (MHz)
Figure 13. Group Delay at 5.5MHz (PAL) With and Without Peaking Capacitor
14
ML6427
LEGEND
JPx
MOVABLE
JUMPER
5V
FB1
GND
C12
1µF
C13
0.1µF
FB2
VCCA
1
C10
1µF
C11
0.1µF
2
PERMANENT
SHORT
3
220µF
R24 75Ω
CVOUT1
220µF
R23 75Ω
CVOUT2
YOUT1
VCCO
C14
CVIN1
6
0.1µF
17
22
19
5
U1
R1 75Ω
X2
C15
CVIN2
0.1µF
C16
0.1µF
C17
0.1µF
C18
C20
R5 75Ω
JP2
1
1
FOURTH
ORDER
FILTER
7
8
MUX
FOURTH
ORDER
FILTER
X2
MUX
FOURTH
ORDER
FILTER
X2
MUX
FOURTH
ORDER
FILTER
X2
14
24
9
10
C19
CIN1
3 2
MUX
0.1µF
R4 75Ω
0.1µF
X2
3
4
R3 75Ω
YIN2
11
12
0.1µF
1
13
C3
C34
CVOUT2
YOUT1
330pF
18
C4
220µF
R21 75Ω
YOUT2
16
P2—EVC
13
14
15
C5
220µF
15
R20 75Ω
COUT1
5
4
SW1-A
23
SW1-C
5V
SW1-B
5
13
17
JP3
21
2
3
1
1
GND
14
13
24
23
C21
0.1µF
X2
2
JP6
3
C22
0.1µF
C23
0.1µF
C24
0.1µF
C25
0.1µF
C26
0.1µF
MUX
FOURTH
ORDER
FILTER
7
8
MUX
FOURTH
ORDER
FILTER
X2
9
10
MUX
FOURTH
ORDER
FILTER
X2
11
12
MUX
FOURTH
ORDER
FILTER
X2
R9 1kΩ
BIN
R10 1kΩ
GIN
R11 75Ω
6
C27
RIN
R13 75Ω
22
19
16
2
7
3
11
20
18
16
15
19
C6
220µF
R17 75Ω
C7
220µF
R16 75Ω
C8
220µF
R15 75Ω
C9
220µF
R14 75Ω
CVOUT+
Y+
P1—SCART
BOUT
GOUT
ROUT
5
0.1µF
R12 75Ω
C28
17
3
15
X2
3
4
1
21
MUX
R8 1kΩ
2
JP4
U2
CIN2
R22 75Ω
JP1
1
2
220µF
330pF
R6 1kΩ
HSYNCIN
1
C33
20
9
2 3
R7
1kΩ
C2
MUX
R2 75Ω
YIN1
JP5
2
21
0.1µF
C29
1µF
C30
0.1µF
VCCA
C31
0.1µF
C32
0.1µF
VCCO
Figure 14. Typical Application Schematic
15
ML6427
PHYSICAL DIMENSIONS inches (millimeters)
Package: S24
24-Pin SOIC
0.600 - 0.614
(15.24 - 15.60)
24
0.291 - 0.301 0.398 - 0.412
(7.39 - 7.65) (10.11 - 10.47)
PIN 1 ID
1
0.024 - 0.034
(0.61 - 0.86)
(4 PLACES)
0.050 BSC
(1.27 BSC)
0.095 - 0.107
(2.41 - 2.72)
0º - 8º
0.012 - 0.020
(0.30 - 0.51)
0.090 - 0.094
(2.28 - 2.39)
SEATING PLANE
0.005 - 0.013
(0.13 - 0.33)
0.022 - 0.042
(0.56 - 1.07)
0.009 - 0.013
(0.22 - 0.33)
ORDERING INFORMATION
PART NUMBER
TEMPERATURE RANGE
PACKAGE
ML6427CS
0°C to 70°C
24 Pin SOIC (S24)
Micro Linear Corporation
2092 Concourse Drive
San Jose, CA 95131
Tel: (408) 433-5200
Fax: (408) 432-0295
www.microlinear.com
© Micro Linear 1999.
is a registered trademark of Micro Linear Corporation. All other trademarks are the
property of their respective owners.
Products described herein may be covered by one or more of the following U.S. patents: 4,897,611; 4,964,026; 5,027,116; 5,281,862; 5,283,483;
5,418,502; 5,508,570; 5,510,727; 5,523,940; 5,546,017; 5,559,470; 5,565,761; 5,592,128; 5,594,376; 5,652,479; 5,661,427; 5,663,874; 5,672,959;
5,689,167; 5,714,897; 5,717,798; 5,742,151; 5,747,977; 5,754,012; 5,757,174; 5,767,653; 5,777,514; 5,793,168; 5,798,635; 5,804,950; 5,808,455;
5,811,999; 5,818,207; 5,818,669; 5,825,165; 5,825,223; 5,838,723; 5.844,378; 5,844,941. Japan: 2,598,946; 2,619,299; 2,704,176; 2,821,714. Other
patents are pending.
Micro Linear makes no representations or warranties with respect to the accuracy, utility, or completeness of the contents of this publication and reserves
the right to makes changes to specifications and product descriptions at any time without notice. No license, express or implied, by estoppel or otherwise,
to any patents or other intellectual property rights is granted by this document. The circuits contained in this document are offered as possible applications
only. Particular uses or applications may invalidate some of the specifications and/or product descriptions contained herein. The customer is urged to
perform its own engineering review before deciding on a particular application. Micro Linear assumes no liability whatsoever, and disclaims any express
or implied warranty, relating to sale and/or use of Micro Linear products including liability or warranties relating to merchantability, fitness for a particular
purpose, or infringement of any intellectual property right. Micro Linear products are not designed for use in medical, life saving, or life sustaining
applications.
16
DS6427-01