MAX9208(2001) Ver la hoja de datos (PDF) - Maxim Integrated
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MAX9208 Datasheet PDF : 12 Pages
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10-Bit Bus LVDS Deserializers
Table 1. Typical Lock Times
REFCLK
FREQUENCY
16MHz
35MHz
40MHz
DATA
PATTERN
PSEUDORANDOM
DATA
PSEUDORANDOM
DATA
PSEUDORANDOM
DATA
Maximum
0.749µs
0.375µs
0.354µs
Maximum (Clock
Cycles)
11.99
13.14
14.18
Average
0.318µs
0.158µs
0.144µs
Average (Clock
5.09
5.52
5.76
Cycles)
Minimum
0.13µs
0.068µs
0.061µs
Minimum (Clock
Cycles)
2.08
2.37
2.44
Note: Pseudorandom lock performed with 215-1 PRBS pattern, 10,000 lock time tests.
40MHz
SYNC
PATTERNS
0.134µs
5.37
0.103µs
4.11
0.061µs
2.45
into high impedance but LOCK continues to reflect the
status of the serial input. Driving REN high again
enables the ROUT_ and RCLK drivers.
Losing Lock on Serial Data
If one embedded clock edge (rising edge formed by
end/start bits) is not detected, LOCK goes high, RCLK
tracks REFCLK, and ROUT_ stays active but with
invalid data. LOCK stays high for a minimum of two
RCLK cycles. Then, if transitions are detected at the
serial input, the PLL attempts to lock to the serial input.
When the PLL locks to serial input data, LOCK goes
low, RCLK tracks the serializer reference clock (TCLK),
and ROUT_ is valid on the second selected strobe
edge of RCLK after LOCK goes low. A minimum of two
embedded clock edges in a row are required to regain
lock to the serial input after LOCK goes high.
For automatic resynchronization, LOCK can be con-
nected to the MAX9205/MAX9207 serializer SYNC1 or
SYNC2 input. With this connection, when LOCK goes
high, the serializer sends sync patterns until the deseri-
alizer locks to the serial input and drives LOCK low.
Input Fail-Safe
When the serial input is undriven (a disconnected cable
or serializer output in high impedance, for example) an
on-chip fail-safe circuit (Figure 2) drives the serial input
high. The response time of the fail-safe circuit depends
on interconnect characteristics. With an undriven input,
LOCK may switch high and low until the fail-safe circuit
takes effect. The undriven condition of the link can be
detected in spite of LOCK switching since LOCK is
high long enough to be sampled (LOCK is high for at
least two RCLK cycles after a missed clock edge and
RCLK keeps running, allowing sampling). If it is
required that LOCK remain high for an undriven input,
the on-chip fail-safe circuit can be supplemented with
external pullup bias resistors.
Deserializer Jitter Tolerance
The tJT parameter specifies the total zero-to-peak input
jitter the deserializer can tolerate before a sampling
error occurs (Figure 9). Zero-to-peak jitter is measured
from the mean value of the deterministic jitter distribu-
tion. Sources of jitter include the serializer (supply
noise, reference clock jitter, pulse skew, and intersym-
bol interference), the interconnect (intersymbol interfer-
ence, crosstalk, within-pair skew, ground shift), and the
deserializer (supply noise). The sum of the zero-to-peak
individual jitter sources must be less than or equal to
the minimum value of tJT.
For example, at 40MHz, the MAX9205 serializer has
140ps (p-p) maximum deterministic output jitter. The
zero-to-peak value is 140ps/2 = 70ps. If the intercon-
nect jitter is 100ps (p-p) with a symmetrical distribution,
the zero-to-peak jitter is 50ps. The MAX9206 deserializ-
er jitter tolerance is 720ps at 40MHz. The total zero-to-
peak input jitter is 70ps + 50ps = 120ps, which is less
than the jitter tolerance. In this case, the margin is
720ps - 120ps = 600ps.
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