ACS102A 데이터 시트보기 (PDF) - Semtech Corporation

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ACS102A

Fiber Modem

Semtech Corporation 

Advanced Communications

Using drift lock, synchronisation described above depends on a

difference in the XTAL frequencies 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 0ppm).

Active Lock Mode

Active lock mode may be used to accelerate synchronisation of a

pair of communicating modems. This mode synchronises the

modems in less than 3 seconds by adjusting the machine cycles of

the modems. Active lock reduces the machine cycle of the device

by 0.5 % ensuring rapid lock. After synchronisation the machine

cycle reverts automatically to normal.

Only one device may be configured in active lock mode at any one

time. Active lock mode is usually invoked temporarily on power-up.

This can be achieved on the ACS102A by connecting DM1 to an RC

arrangement, i.e. with the capacitor to 5V and the resistor to GND, to

create a 5V à 0V ramp on power-up. The RC time constant should

be Ca. 5 seconds. Active lock will succeed even when

communicating devices are driven from clocks derived from a single

source (0ppm).

Random Lock

This mode achieves moderate locking times (typically 5 seconds,

worst case 10 seconds) with the advantage that the ACS102’s are

configured as peers. Communicating modems may be permanently

configured in this mode by hard wiring the DM pins.

Random lock will succeed even when communicating devices are

driven from clocks derived from a single source (0ppm). 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 10 seconds

the communicating modems will achieve synchronisation with one

establishing itself as an active lock modem and the other

establishing itself as a drift lock modem. On subsequent attempts to

lock, synchronisation will be achieved within 3 seconds. It is only

necessary to apply reset to one device in the communicating pair to

initiate an arbitration process.

Since memory lock uses on-chip storage, loss of power to the

modem will require a new reset (PORB=0). Furthermore, should

there be a need to synchronise with a third modem a 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 given in Table 4 :

Device A

Mode

Device B

Mode

Locking Speed

Drift

Drift

Drift

Drift

Active

Active

Active

Random

Random

Memory

Drift

Active

Random

Memory

Active

Random

Memory

Random

Memory

Memory

Drift

Active

Random

Random

Not allowed

Random

Random

Random

Random

Active (Random on first synchronisation)

Table 4. Mixing lock modes

PORB

The Power-On Reset or PORB resets the device if forced Low for

100ms or more. This pin should be connected as figure 4.

Crystal Clock

Normally, a parallel resonant crystal will be connected between the

pins XLI and XLO with the appropriate padding capacitors. The

ACS102A Data Sheet

crystal oscillator will operate with padding capacitors of value 0 -50pF,

and the designer should endeavour to use padding capacitors of low

value since this will ensure the lowest power consumption. The

ACS102A has been designed to operate with a crystal tolerance of +/

- 250ppm giving a relative tolerance between communicating modem

pairs of 500ppm. This wide tolerance will support the use of low value

padding capacitors.

Alternatively, XLI may be driven directly by an external clock. The

clock frequency for the purpose of this specification is referred to as

the XTAL frequency. The operational range for the XTAL frequency is

5 - 27MHz, though communicating devices must use the same

nominal value.

DCDB

The Data Carrier Detect (DCDB) signal goes Low when the modems

are synchronised ('locked') and ready for data transmission. Prior to

lock (DCDB = High), the data channel output RxD will be forced Low

and the handshake outputs CTS and DSR will be forced High.

The status of DCDB is also given by the HBT pin. See section headed

HBT Status pin.

CNT Capacitor

The CNT value is inversely proportional to the XTAL frequency. The

capacitor is connected between pins CNT and GND. A 20 %

tolerance on CNT is sufficient. For a XTAL frequency range of

5 to 27MHz the recommended value of the capacitor on CNT is from

2

47nF at 5MHz, 22nF at 10MHz down to 10nF at 27MHz . A ceramic

type is required to ensure low leakage. The CNT capacitor value has

an effect on the initial locking time and the receiver sensitivity limit.

Higher values giving improved sensitivity and lower values giving

faster locking.

ERL (Error Detector)

This signal can be used to give an indication of the quality of the

optical link. Even when a DC signal is applied to the data and

handshake inputs, the ACS102A modem transmits up to 200kbps

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, 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.

Please note that ERL detects coding errors and not data errors,

nevertheless because of the complexity of the coding rules on the

ACS102A the absence of detected errors on this pin will give a good

indication of a high quality link.

HBT Status pin ('Heartbeat' Indicator LED)

The ACS102A HBT pin 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 8 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) 3.2 % of the total time, the

HBT requires little power which may be further reduced by employing

high efficiency LEDs.

Powered-up, but not locked

Frequency (Hz):

XTAL / 3.89 * 106

Duration (s):

61,440 / XTAL

On time (%):

3.2 % of time.

With 10MHz XTAL :

Frequency:

2.5Hz (approx.)

Duration:

6.1ms (approx.)

Powered-up and locked

Frequency (Hz):

Duration (s):

On time (%):

With 10MHz XTAL :

XTAL / 15.36 * 106

61,440 / XTAL

0.4 % of time.

Frequency:

0.65Hz (approx.)

Duration:

6.1 ms (approx.)

5

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