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PDF ACS401 Data sheet ( Hoja de datos )
| Número de pieza | ACS401 | |
| Descripción | Acapella Optical Modem IC | |
| Fabricantes | Semtech Corporation | |
| Logotipo |  |
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Acapella Optical Modem IC
ACS401 Main Features:
* Enables up to four full-duplex serial transmission channels
through a single fiber optic cable, providing eight virtual fiber
paths.
* Two additional low speed handshake signals.
* Supports Ping Pong LED (PPLED) and LASER Duplex
Devices (LDD) for single fiber applications or dual fiber
applications using low cost LED/LASER emitters and PIN
Diode receiver.
* Link lengths up to 95 km with appropriate Laser.
* Maximum data rate 128 kbps - optimised for talk-set
applications.
* Typical 7 mA (average) current consumption, including
LASER drive current.
* Digital mode, allowing the user to add an external amplifier.
Also enables the ACS401 to be used in non-fiber applications.
* Bit Error Rate (BER) of 10-9
Equivalent block diagram of ACS401.
TRC
TxD1
TxD2
TxD3
TxD4
TxCL
RxD1
RxD2
RxD3
RxD4
RxCL
VA+
VD+
GND
Digital
Filter
FIFO
Compress
3B4B
Encoder
Digital
Filter
FIFO
Decompress
3B4B
Decoder
LED Driver
PIN Receiver
Control Data
Status
Control Logic
434
LAP
LAN
PINP
PINN
PPLED
Single
Fiber
CNT
GND
XTAL
XO1 XI1 XO2 XI2
HBT CLK9 ERRC ERRL
DR(1:3) DM(1:3) DP(1:4) PORB CKC
General Description:
The ACS401 is a complete optical-modem controller/
driver/receiver IC, supporting various user programmable, full-
duplex, synchronous data rates to 128 kbps over a single fiber.
Communicating modems automatically maintain synchronis-
ation with each other such that the receive phase of one modem
is lined up with the transmit phase of the other, compensating for
the propagation delay presented by the link. Link lengths from
zero to maximum distance, up to 95 km, are catered for
automatically.
1 page  
Whilst a device is responding to a request for remote loopback
from the far-end, requests from the near-end to initiate remote
loopbacks will be ignored.
Drift Lock
Communicating modems attain a stable state where the ‘transmit’
window of one modem coincides with the ‘receive’ window of the
other, allowing for delay through the optical link. Adjustments to
machine cycles are made automatically during operation, to
compensate for differences in XTAL frequencies which would
otherwise cause loss of synchronisation.
Drift lock synchronisation described above, depends on a
difference in the XTALfrequencies at each end of the link, and the
greater the difference the faster the locking. Therefore, if the
difference between XTAL frequencies is very small (a few ppm),
automatic locking may take tens of seconds or even minutes.
Drift lock will not operate if the two communicating devices are
driven by a clock derived from a single source (i.e. tolerance of 0
ppm).
Active Lock
Active lock mode may be used to accelerate synchronisation of a
pair of communicating modems. This mode synchronises the
modems with less than 3.0 seconds delay, by adjusting the
machine cycles of the modems. Active lock reduces the machine
cycle of the device by 0.3 % ensuring rapid lock. After
synchronisation the machine cycle reverts automatically to
normal.
Note that only one device can be configured in active lock mode
at any one time, and thus the DM(1:3) pins must not be
permanently wired High on both devices in a production system.
Active lock mode is usually invoked temporarily on power-up.
This can be achieved on the ACS401 by connecting DM1, DM2
and DM3 together, and attaching that node to an RC arrangement
with the capacitor to 5 V and the resistor to GND, to create a 5 V
0 V ramp on power-up. The RC time constant should be > 5
seconds.
Active lock will succeed even when communicating devices are
driven from clocks derived from a single source (i.e. 0 ppm).
Random Lock
This mode achieves moderate locking times (typically 4 seconds,
worst case 12 seconds) with the advantage that the ACS401’s are
configured as peers. Communicating modems may be
permanently configured in this mode (i.e. with hard-wired DM(1:3)
pins).
Random lock operates even when communicating devices are
driven from clocks derived from a single source. Random lock
mode is compatible with drift lock and active lock.
Memory Lock
Following the assertion of a reset (PORB = 0) communicating
devices will initiate an arbitration process where within 12 seconds
the communicating modems will achieve synchronisation. One
establishing itself as an active lock modem and the other
establishing itself as a drift lock modem. On subsequent attempts
to lock, typically where the fiber has been disconnected and a new
fiber inserted, synchronisation will be achieved within 3 seconds.
It is only necessary to apply PORB to one device in the
communicating pair to initiate an arbitration process.
Since memory lock status (active or drift) uses on-chip storage,
loss of power to the IC will require a new reset (PORB = 0).
Furthermore, should there be a need to synchronise with a third
modem, reset will again be required.
Mixing Lock modes
It is possible to mix all combinations of locking modes once the
modems are locked, however, prior to synchronisation two
modems configured in active lock will not operate. The effect of
mixing locking modes on locking speed is tabulated below:
Device A
Mode
Drift
Drift
Drift
Drift
Active
Active
Active
Random
Random
Memory
Device B
Mode
Drift
Active
Random
Memory
Active
Random
Memory
Random
Memory
Memory
Locking Speed
Drift
Active
Random
Random
Not allowed
Random
Random
Random
Random
Active*
* Memory lock has random lock speed for the first synchronisation
HBT Status pin (‘Heartbeat’ Indicator LED)
The ACS401 HBTpin affords a method of driving a display LED in
a manner which is sympathetic to low power consumption. The
HBT pin is pulsed to indicate ‘locked’status (DCDB = 0) and ‘out
of lock’ status (DCDB = 1). The frequency of pulses is 16 times
greater for ‘out of lock’ than for ‘lock’. The LED ‘on’ indicates
power-up whilst the frequency of pulsing denotes locking status.
Since the display LED is on for at most 6.4 % of the total time, the
HBT requires little power which may be further reduced by
employing high efficiency LEDs. The formulas below presume
‘standard’ mode of operation; for ‘double’ mode the XTAL value
should be divided by 2.
Powered-up, but not locked
Frequency (Hz): XTAL / 1.152 * 106
Duration (s):
73,728 / XTAL
On time (%):
6.4 % of time.
With 9.216 MHz XTAL and ‘standard’ mode
Frequency:
8 Hz (approx.)
Duration :
8 ms (approx.)
Powered-up and locked
Frequency (Hz): XTAL/ 18,432
Duration (s):
73,728 / XTAL
On time (%):
0.4 % of time.
With 9.216 MHz XTAL and ‘standard’ mode
Frequency:
0.5 Hz (approx.)
Duration :
8 ms (approx.)
The HBT pin is active High and can supply up to 16 mA at a
voltage of > VDD - 0.5 Volts. The display LED should be placed
between the HBTpin and GND with a series resistor. The resistor
value is a function of the efficiency of the display LED, and the
power budget.
Example: Calculating the HBT resistor value
LED on voltage:
VDD (ACS401):
Resistor voltage:
Current to LED:
Resistor value:
2.0 V
5.0 V
3.0 V
2 mA (high efficiency LED)
3 / 2 * 10-3 = 1500 Ω
Note: The LED referred to in this section is of the inexpensive
display type and should not be confused with the LED that
interfaces with the fiber optic cable itself.
ERC and ERL (Error Detector)
These signals can be used to give an indication of the quality of
the optical link. Even when a DC signal is applied to the data,
handshake and TxCL inputs, the ACS401 modem transmits
approximately 40 kbps over the link in each direction. This control
data is used to maintain the timing and the relative positioning of
‘transmit’and ‘receive’ windows.
The transmit and control data is constantly monitored to make
sure it is compatible with the 3B4B format. If a coding error is
detected than ERL will go High and will remain High until reset.
ERL may be reset by asserting PORB or by removing the fiber-
optic cable from one side of the link thereby forcing the device
temporarily out of lock.
5 Page | ||
| Páginas | Total 8 Páginas | |
| PDF Descargar | [ Datasheet ACS401.PDF ] | |
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