Datasheet
ADV3200/ADV3201
Rev. 0 | Page 29 of 36
APPLICATIONS INFORMATION
PROGRAMMING
The ADV3200/ADV3201 are programmed serially through a
193-bit serial word that updates the matrix and the state of the
sync-tip clamps each time the part is programmed.
Serial Programming Description
The serial programming mode uses the CLK, DATA IN,
UPDATE
, and
CS
device pins. The first step is to assert a low
on
CS
to select the device for programming. The
UPDATE
signal should be high during the time that data is shifted into
the serial port of the device. If
UPDATE
is low, the data is still
shifted in, and the transparent, asynchronous latches allow the
data to reach the matrix. This causes the matrix to try to update
itself to every intermediate state defined by the shifted-in data.
The data at DATA IN is clocked in at every rising edge of CLK.
A total of 193 bits must be shifted in to complete the program-
ming. For each of the 32 outputs, there are five bits (D4 to D0)
that determine the source of its input followed by one bit (D5)
that determines the enabled state of the output. If D5 is low
(output disabled), the five associated bits (D4 to D0) do not
matter because no input is switched to that output.
The first bit shifted into the logic is used to enable or disable
the sync-tip clamps. If this bit is low, the sync-tip clamps are
disabled; otherwise, they are enabled.
The sync-tip clamp bit is shifted in first, followed by the most
significant output address data (OUT31). The enable bit (D5) is
shifted in first, followed by the input address (D4 to D0) entered
sequentially with D4 first and D0 last. Each remaining output is
programmed sequentially, until the least significant output
address data is shifted in. At this point,
UPDATE
can be taken
low, which causes the device to be programmed according to
the data that was just shifted in. The second-rank latches are
asynchronous and, when
UPDATE
is low, they are transparent.
If more than one ADV3200/ADV3201 device is to be serially
programmed in a system, the DATA OUT signal from one
device can be connected to the DATA IN of the next device to
form a serial chain. All of the CLK and
UPDATE
pins should be
connected in parallel and operated as described previously. The
serial data is input to the DATA IN pin of the first device of the
chain, and it ripples through to the last. Therefore, the data for
the last device in the chain should come at the beginning of the
programming sequence. The length of the programming sequence
is 193 bits multiplied by the number of devices in the chain.
Reset
When powering up the ADV3200/ADV3201, it is usually
desirable to have the outputs come up in the disabled state. The
RESET
pin, when taken low, causes all outputs to be disabled.
After power-up, the
UPDATE
pin should be driven high prior
to raising
RESET
.
Because the data in the shift register is random after power-up,
it should not be used to program the matrix, or the matrix can
enter unknown states. To prevent this, do not apply a logic low
signal to
UPDATE
initially after power-up. The shift register
should first be loaded with the desired data, and then
UPDATE
can be taken low to program the device.
The
RESET
pin has a 25 k pull-up resistor to DVCC that can
be used to create a simple power-on reset circuit. A capacitor
from
RESET
to ground holds
RESET
low for some time while
the rest of the device stabilizes. The low condition causes all the
outputs to be disabled. The capacitor then charges through the
pull-up resistor to the high state, thus allowing the full program-
ming capability of the device.
The
CS
pin has a 25 k pull-down resistor to DGND.
AC COUPLING OF INPUTS
Using ac-coupled inputs presents a challenge for video systems
operating from low supply voltages or from a single 5 V supply.
In NTSC and PAL video systems, 700 mV is the approximate
difference between the maximum signal voltage and the black
level, assuming that sync has been stripped. However, as shown
in Figure 99, a dynamic range of twice the maximum signal
swing is required if the inputs are to be ac-coupled. A solution
to this extended requirement for dynamic range is the sync-tip
clamp feature.
+700mV
–700mV
+5V
GND
V
AVG
V
AVG
V
SIGNAL
V
REF
V
REF
WHITE LINE WITH BLACK PIXEL
BLACK LINE WITH WHITE PIXEL
V
INPUT
= V
REF
+ V
SIGNAL
V
REF
~ V
AVG
V
REF
IS A DC VOLTAGE
SET BY THE RESISTORS
07176-102
Figure 99. Pathological Case for Input Dynamic Range