SEMTECH ACS102A

100 SERIES
ACS102A Revision 1.6 September 2000
Advanced Communications
ACS102A FiberACS102A
Modem
Data Sheet
Features
*
Full duplex serial transmission over single/twin fiber.
*
Link lengths up to 25km.
*
Supports asynchronous data rates from DC to 162kbps.
*
Full diagnostic modes - Remote and Local loopback.
*
Ultra low power consumption, typically 2-3mA, which could be
extracted from the RS-232 port for self powered applications.
*
Uses a single Ping Pong LED or Laser Duplex Device for single fiber
applications, low cost LED/PIN or Laser/PIN combinations for twin
fiber applications.
*
Additional operating mode to support PIN with integrated TIA.
*
Supports 3 additional low frequency asynchronous channels or
the RS-232 handshake signals.
*
Digital and differential voltage input modes, plus modes for non
fiber applications - RF
*
Bit Error Rate (BER) < 10-9
*
Available in 44 pin TQFP (part no: ACS102A-TQ) and 44 pin
PLCC (part no: ACS102A-PL) packages.
A
S
C
0
1
A
2
TRC
TxD
Digital
Filter
Data
Compress
FIFO Time
Compress
3B4B
Encoder
RxD
Digital
Filter
Data
Decompress
FIFO Time
Decompress
3B4B
Decoder
RS-232 Interface
DCDB CTS
DSR RIO
RTS
PPLED
LDD
LED/PIN
Laser/PIN
combinations
LED/Laser
Driver
LED/PIN
Receiver
Control Logic
DTR RII
DR(3:1) DM(3:1) HD(2:1) DP
HBT ERL PORB
Equivalent Block Diagram of ACS102A
Description
The ACS102A is a complete controller, driver and receiver IC, supporting fullduplex asynchronous transmission from DC to 162kbps over a single serial link.
Although primarily designed for single optical fibre applications, any other simple
serial media may be used. The ACS102A is optimised for very low power
consumption, consuming only 2 - 3mA at RS-232 data rates including power
provided to the LED and 'heartbeat' monitor. In applications where the power is
extracted from the RS232 data lines, this leaves a generous amount of power left
for any power extraction and RS-232 level shifting circuitry.
The ACS102A employs data compression and time compression techniques,
affording high launch power in short bursts, leading to a low average power
consumption. The advantage of this approach is that high link budgets can be
achieved with inexpensive optical components.
For example, the recommended set-up for RS-232 applications (19.2kbps +
handshake signals) assumes that the LED is driven with a peak current of
approximately 15.4mA for 6 % of the time. The machine cycle is short enough to
facilitate power supply smoothing with a small external capacitor in the region of
100µF.
1
2
Advanced Communications
ACS102A Data Sheet
Single/Dual Fiber Modem for Asynchronous Data Rates from DC to 160kbps
Transmitter and Receiver Functions
Mode 4 - Single Fiber 3-pin LASER/PIN mode
This device offers one high speed and three low speed full duplex
channels to the user in a completely transparent way, appearing as
4 full duplex channels even though the medium connecting the
devices may only be a single fiber link.
Setup : DP5=0, DP4=0, DP3=1, DP2=0, DP1=1
This is a single-fiber mode where the LASER is used for transmission and the monitor PIN diode within the LASER is used for
reception. Differential reception from the PIN diode is used to
maximise sensitivity. Connections are shown below :
Data from the TxD and low frequency channels is time
compressed in an internal FIFO and sent over the fiber link in a
burst within a predefined window. The device at each end of the
link automatically synchronise with each other such that the
transmit and receive windows are interleaved. The TxD input data
of the transmitting modem is also data compressed. The 3B4B
encoding method is used for communication between ACS102As,
thus ensuring that there is no DC component in the signal. The
encoding and decoding is transparent to the user.
LASER
LAP
PINP
LAN
In the receiving modem, 3B4B encoding ensures easy extraction of
the bit-clock. The received data is filtered, decoded, and then
stored in the output memory. The memory provides time expansion,
de-jittering and frequency compensation functions. The data is then
decompressed and directed to the RxD output pin, appearing after a
minimal delay, in the same format as that presented at the TxD pin
at the far end.
2
Fiber
3-pin LASER single fiber mode
Mode 5 - Single Fiber 4-pin LASER/PIN mode
Setup : DP5=0, DP4=0, DP3=1, DP2=0, DP1=0
This is a single-fiber mode where the LASER is used for transmission and the monitor PIN diode within the LASER is used for
reception. Differential reception from the PIN diode is used to
maximise sensitivity. Connections are shown below :
Operational Modes
The ACS102A is compatible with the ACS102 but offers over twice
the max data rate and incorporates the laser interface modes
previously associate with the ACS402. The ACS102A is a pin and
functional compatible replacement for both the ACS102 and
ACS402. The following sections detail the operating modes for all
configurations of LED, LASER and LED/PIN or LASER/PIN
combinations. Additional modes are also described for new ways of
interfacing the device with external PIN / amplifier modules.
LASER
LAP
Fiber
PINN
PINP
LED Interface Modes
LAN
Mode 1 - Single Fiber LED mode
4-pin LASER single fiber mode
Setup : DP5=0, DP4=0, DP3=0, DP2=1, DP1=0
This is the operational mode for single fiber transmission with a
PPLED. The LED is used for both transmission and reception of
data over the fiber. An example circuit diagram showing the
necessary connections is shown in figure 4. This also shows an
example circuit for interfacing to the RS232 voltage levels of a PC
serial port.
LASER Duplex Device Use
The Laser duplex device is composed of a 3 or 4 pin Laser for
transmission and a PIN diode for reception in a single housing.
Mode 3, as detailed previously is used for interfacing to these
devices. The Duplex devices are driven by the ACS102A in a halfduplex manner, even though to the user it appears as a full duplex
link. As a consequence potential cross-talk between the transmitter and receiver is ignored, allowing excellent performance from
low cost components.
Mode 2 - Dual Fiber LED/PIN mode
Setup : DP5=0, DP4=0, DP3=0, DP2=1, DP1=1
This is a twin-fiber mode where the LED is used for transmission
and a separate PIN Diode is used for reception. This allows the use
of less expensive standard LEDs and PINs rather than bi-directional
PPLEDs or Duplex devices. An example circuit diagram showing
the necessary connections is shown in figure 5.
Additional Alternative Modes
The previous modes detail the most common setups for most
typical LED, LED/PIN or LASER/PIN combinations. Many other
possible operating modes are possible via the DP1-5 pins setups.
LASER Interface Modes
Some of the other less common connection combinations are
shown below. These include modes for using a LASER as a
receiver as well as a transmitter in a single fiber link, where the
LASER device supports this, receiving from both the LASER and
monitor PIN, and modes for digital interfacing to external PIN/
transimpedance amplifier (TIA) modules. Only use those setups
on DP1-5 indicated in this specification, other pin combinations
may activate unpublicised functional or test modes which may lead
to damage of the LASER, where this is used.
Mode 3 - Dual Fiber LASER/PIN mode
Setup : DP5=0, DP4=1, DP3=0, DP2=1, DP1=0
This is a twin-fiber mode where the LASER is used for transmission
and a separate PIN Diode is used for reception. An example circuit
diagram showing the necessary connections is shown in figure 6.
Differential reception from the PIN diode is used to maximise
sensitivity. Since PINP is also used for LASER current control via
monitoring of the monitor diode current, the LAP and LAN pins are
automatically floated during data reception.
Mode 6 - Single Fiber 4-pin LASER/PIN mode (Las & mon recv)
Setup : DP5=0, DP4=0, DP3=0, DP2=0, DP1=0
Either 3 or 4 pin LASERs may be used in this mode. For 4 pin
LASERS the extra pin of the monitor diode cathode is connected
to the LASER anode, the same as it is shown in figure 6 with the
internal connection of a typical 3-pin LASER.
This is a single-fiber mode where the LASER is used for transmission and the LASER and the monitor PIN diode within the LASER is
used for reception. Connections are as in mode 5.
2
Advanced Communications
ACS102A Data Sheet
Mode 7 - Single Fiber 3-pin LASER/PIN mode (Laser recv)
LASER current control
Setup : DP5=0, DP4=0, DP3=0, DP2=0, DP1=0
The LASER output current must be set for each individual device
in accordance with the manufacturer’s recommendations. The
output current to the LASER is controlled by a variable resistor
(Rtrc) between TRC and ground. The lower the value of Rtrc the
greater the current. The minimum value of Rtrc is 800Ω. The
ACS102A derives and controls the average optical power being
produced by measuring the current in the LASER's monitor PIN
diode and integrating this measurement using the capacitor on the
CTX pin, which is typically 10nF. A control loop is established
which works to maintain the average optical power at a constant
level whilst parameters such as voltage, temperature and LASER
efficiencies may vary. The average optical power is always one
half of the peak power since the LASER is driven between full on
and full off, with an average mark-space ratio of 50%. An example
circuit arrangement is shown in figure 6.
This is a single-fiber mode where the LASER is used for transmission and only the LASER is used for reception. Connections are as
in mode 4.
Preamp Interface modes
Mode 8 - Preamp Voltage Input & LED Drive
Setup : DP5=1, DP4=0, DP3=1, DP2=0, DP1=0, NSB=0
This is a mode for use with external amplifier and PIN modules. An
LED is used for transmission and connected as normal with its
anode to LAP and cathode to LAN. The differential voltage from an
external PIN/TIA module is connected to PINN and PINP via
100pF capacitors to provide DC isolation. The signals should be
connected such that PINP is connected to the TIA output that goes
high when light is received. A single input can also be applied from
a single ended PIN/TIA by feeding the input to PINP only, PINN is
left floating. This mode uses the new NSB pin, in all other modes
this pin should be left disconnected or connected to VA+.
Adjustment Procedure
Select the appropriate LASER drive mode using the pins DP1-5
(see section headed Operational Modes). The LASER drive
current and hence transmitted optical power is set by adjusting
Rtrc until the required output power is obtained, taking account of
the maximum allowed drive current set by the LASER manufacturer.
Mode 9 - Preamp Voltage Input & LASER Drive
Setup : DP5=1, DP4=0, DP3=1, DP2=0, DP1=1, NSB=0
There are two ways of measuring the output power and drive
current, either dynamically in the normal operating mode or
statically by setting the pin SETB low.
This is a mode for use with external amplifier and PIN modules. A
LASER is used for transmission and connected as normal as
described under mode 3. The differential voltage from an external
PIN/TIA module is connected to PINN and PINP via 100pF
capacitors to provide DC isolation. The signals should be
connected such that PINP is connected to the TIA output that goes
high when light is received. A single input can also be applied from
a single ended PIN/TIA by feeding the input to PINP only. With a
LASER drive the PINN and PINP inputs are also connected to the
LASER monitor diode. This may induce extra noise but should not
interfere with the operation. This mode uses the new NSB pin, in
all other modes this pin should be left disconnected or connected
to VA+.
If measuring power dynamically during the normal mode, the
output from the laser can be measured using an optical-power
meter that is capable of detecting peak optical-power. If an
averaging optical power meter is employed then a correction factor
of 16 must be used to obtain the peak value :
LASER(peak power) = Laser(average power) * 16.
To measure power statically, the SETB pin must be pulled low to
ground. This forces the device to constantly transmit through the
LASER at a fixed level. This fixed level will be equivalent to half of
the peak level, since the normal control loop within the device
works to control the average power level through integrating out
the alternating data pulses.
Digital interface modes
Mode 10 - Digital Data Input & LASER Drive
LASER(peak power) = Laser power(with SETB=0) * 2.
Setup : DP5=0, DP4=1, DP3=1, DP2=0, DP1=0
Since all currents are static in this mode, a simple optical power
meter can be used and the drive current in the laser can be easily
measured by connecting an ammeter between pin LMN and VA+.
LMN provides a convenient means of monitoring the LASER drive
current through the relationship :
This is a mode for use with external amplifier and PIN modules that
provide fully digital output levels. A LASER is used for transmission
and connected as normal as described under mode 3. The output
from an external PIN/TIA module is connected to CNT. The
polarity of the input should be such that CNT that goes high when
light is received.
LASER(current) = 100 x LMN(current)
+/- 8%.
Dynamic measurement of the LMN current is also possible by
connecting a resistor to LMN and measuring the voltage pulses.
Mode 11 - Digital Data Input & LED Drive
Setup : DP5=1, DP4=1, DP3=0, DP2=1, DP1=0
Data-Rate Selection
This is a mode for use with external amplifier and PIN modules that
provide fully digital output levels. An LED is used for transmission
and connected as normal as shown in figure 5. The output from an
external PIN/TIA module is connected to CNT. The polarity of the
input should be such that CNT that goes high when light is
received.
The ACS102A benefits from data compression circuitry which
reduces power consumption and improves the BER (Bit Error
Rate). The compression technique employed, demands a
minimum TxD data-bit time of 10 sample-clocks. This defines the
maximum data rate:
Maximum data rate = sample-clock/10
Transmit Current Control
However, an allowance must be made for any variation in the TxD
data-bit period to accommodate frequency variation and jitter.
Hence the maximum data rates specified in the following are
decreased by 10% to include a sufficient safety margin.
LED current control
The LED transmit current is not critical though it is important not to
exceed the LED manufacturer's recommendation for maximum
current. The current is controlled by a resistance Rtrc connected
between TRC and GND. The lower the value of Rtrc the greater
the current. The lower limit for Rtrc is 800Ω while a practical
maximum is 40kΩ.
The ACS102A includes an input pulse shaper which ensures that
the system is very tolerant to jitter, and helps achieve a maximum
data-rate close to the theoretical maximum of sample-clock/10
(bps). The pulse shaper will expand data pulses of less than 10
clock-samples to meet the compression criteria. This is performed
on up to three consecutive data-bits which fail to meet the
minimum pulse width criteria.
The LED current is inversely proportional to Rtrc while Rtrc > 800Ω.
LED current = (100 / Rtrc) +/- 25 %
3
2
Advanced Communications
DR3
DR2
DR1
XTAL
Clock
0
1
1
1
1
1
1
1
0
0
1
1
1
1
1
0
1
0
1
1
1
10MHz
10MHz
10MHz
10MHz
10MHz
20MHz
27MHz
Sample
Clock
XTAL/160
XTAL/80
XTAL/40
XTAL/20
XTAL/15
XTAL/15
XTAL/15
ACS102A Data Sheet
maximum frequency will not be compressed beyond the standard
CF of 1.
Max TxD
Data Rate
Super-compress mode provides benefits where the user is
interested in low average power consumption (e.g. battery life)
rather than peak power. If the intended system is idle for most of
the time with periodic bursts of activity, the additional data
compression afforded will approach a CF of 3.
5.6kbps
11kbps
22kbps
45kbps
60kbps
120kbps
162kbps
Locking
Table 1. TxD Data-Rate Selection
To achieve low power consumption the ACS102A is active for a
small percentage of the frame (machine-cycle) known as the
'transmit' window and the 'receive' window, collectively these
windows are known as the 'active time'. Outside the 'active time'
the device is largely dormant accept for the maintenance of the
oscillator and basic 'house-keeping' functions.
Table 1. shows the maximum TxD data rate, which includes a 10%
tolerance margin, when using various frequency crystals, other
sample-clock frequencies may be generated by using the
appropriate value XTAL in combination with the divide constant
selected by DR(1:3) namely 15,20,40,80 or 160.
The advantage of using a slower crystal and a lower sample clock
is the reduced power consumption of the device.
Communicating modems attain a stable state known as 'locked',
where the 'transmit' window of one modem coincides with the
'receive' window of the other, allowing for the delay through the
optical link.
Adjustments to machine cycles are made
automatically during operation, to compensate for differences in
XTAL frequencies which cause loss of synchronisation.
RS-232 Handshake Signals / Low Frequency Data Channels
2
Three additional low frequency data channels are provided on the
ACS102A which are often used for the RS-232 handshake signals.
The RS-232 handshake signals comprise the set RTS, CTS, DTR
and DSR. These are treated as pass through data channels rather
than using local handshaking. Hence the status of inputs RTS and
DTR appear at the far-end outputs CTS and DSR respectively. An
extra data channel has also been provided, which may be used for
sending the RS232 Ring Indicator signal, for example. The input
and output lines are RII and RIO respectively.
The ACS102A locking algorithm is statistical, and consequently
the locking time will differ on each attempt to lock.
Diagnostic and Locking Modes
The diagnostic and operational modes, shown in Table 3, are
selected using the DM pins.
The transmission method employed on the ACS102 has been
designed to give low skew (1 - 2 data-bits) on the main RTS, CTS,
DTR and DSR handshake signals relative to the main TxD/RxD
data channel, while maintaining low power consumption.
The handshake signals are updated by two stimuli:
i.
an internal interval timer at a frequency proportional to the
XTAL; at 10.0MHz this is approximately 1.6ms.
ii.
changes detected on RTS and DTR.
HD1
0
0
1
1
0*
1
0
1
Sampling
Frequency
600
10
5
2.5
Hz
kHz
kHz
kHz
DM2
DM1
0
0
0
1
1
1
0
0
1
0
1
1
0
1
0
1
0
1
Mode
Lock
Full-duplex
Full-duplex
Full-duplex
Local loopback
Remote loopback
Full-duplex
Drift
Active
Memory
Random
Random
Random
Table 3. Diagnostic and operational modes
Local Loopback
The maximum bandwidth for the handshake signals may be
programmed using pins HD(1:2) in accordance with the Table 2.
HD2
DM3
In local loopback mode TxD data is looped back inside the near-end
modem and appears at its own RxD output. RTS, DTR and RII are
also looped back appearing at their own CTS, DSR and RIO outputs
respectively. The data is also sent to the far-end modem and
synchronisation between the modems is maintained.
Skew
w.r.t. RxD
10 ms.
1 - 2 data bits
1 - 2 data bits
1 - 2 data bits
In local loopback mode data received from the far-end device is
ignored, except to maintain lock. If concurrent requests occur for
local and remote loopback, local loopback is selected.
Table 2. Handshake signal bandwidth allocation
The local loopback diagnostic mode is used to test data flow up to,
and back from, the local ACS102A and does not test the integrity of
the link itself, i.e. local loopback operates independently of
synchronisation with a second modem.
* When HD2 = HD1 = 0 super-compress mode is selected. See
section headed Super-Compress mode.
Handshake data rates which exceed the allocated bandwidth will
be delayed, and consequently result in additional skew between
handshake signals and data.
Remote Loopback
In remote loopback mode, the near-end modem sends a request to
the far-end modem to loopback its received data, thus returning the
data so that it appears at the RxD of the initiating modem. RTS,
DTR and RII follows the same path, returning data back to CTS,
DSR and RIO respectively of the initiating modem. Data also
appears at the far-end modem outputs RxD, CTS, DSR and RIO. In
the process both modems are exercised completely, as well as the
LED/PINs and the fiber optic link. The remote loopback test is
normally used to check the integrity of the entire link from the nearend (initiating) modem. Whilst a device is responding to a request
for remote loopback from the initiating modem (far-end), requests to
initiate remote loopback will be ignored.
The HD pins enable the user to allocate a maximum bandwidth to
the handshake signals and thus limit the power consumption of the
device. The power consumption is, however, dependent on the
actual bandwidth used and not the bandwidth selected. For
example; if the handshake signals were toggled at 1kHz the power
consumption would be the same for an allocated bandwidth of
2.5kHz as it would for an allocation of 10kHz. See section headed
Current and Power Consumption for more details.
Super-Compress mode
This mode is selected when HD2 = HD1 = 0. Super-compress
mode performs a second stage of data compression, thus further
reducing the power consumption of the modem. Normally, data is
compressed in a manner which is independent of the data type. In
super-compress mode, an additional stage of compression further
reduces the data by a factor of 1 to 3 depending on the data itself.
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.
Example: The super-compress stage will compress DC data by an
additional Compression Factor (CF) of 3, whilst data close to the
4
Advanced Communications
ACS102A Data Sheet
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.
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.
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).
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.
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.
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.
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).
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
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.
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.
ERL (Error Detector)
Memory Lock
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.
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.
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.
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.
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.
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)
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):
Duration (s):
On time (%):
With 10MHz XTAL :
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.
XTAL / 3.89 * 106
61,440 / XTAL
3.2 % of time.
Frequency:
2.5Hz (approx.)
Duration:
6.1ms (approx.)
Powered-up and locked
Frequency (Hz):
Duration (s):
On time (%):
With 10MHz XTAL :
Crystal Clock
Normally, a parallel resonant crystal will be connected between the
pins XLI and XLO with the appropriate padding capacitors. The
5
XTAL / 15.36 * 106
61,440 / XTAL
0.4 % of time.
Frequency:
0.65Hz (approx.)
Duration:
6.1 ms (approx.)
2
Advanced Communications
ACS102A Data Sheet
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
HBT pin and GND with a series resistor. The resistor value is a
function of the efficiency of the display LED, and the power budget.
component is dependent on the XTAL frequency while the static
component is dependent on static current loads. (See Calculating
average current and power consumption for details).
Since the peak current can be very much greater than the average
current, it is important to use a substantial smoothing capacitor on
VA+ and VD+. The recommended values are at least 47µF* for
VD+ and 100µF* for VA+. The configuration can be seen in Figure 1.
(* Capacitor tolerance +/- 20 %)
Example: Calculating the HBT resistor value
LED on voltage:
VDD (ACS102A):
Resistor voltage:
Current to LED:
Resistor value:
Average current:
Average power:
2.0V
5.0V
3.0V
2mA (high efficiency LED)
3/2*10-3 = 1500Ω
64µA
0.32mW
Data delay and skew
The Full Duplex Delay (FDD) through the system, which applies to
TxD à RxD, RTS à CTS and DTR à DSR, is shown in Table 5.
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.
DR3
0
1
1
1
1
Power consumption considerations
The power consumption of the ACS102A is a function of the
following:
i.
ii.
iii.
iv.
v.
2
DR2
1
0
0
1
1
DR1
1
0
1
0
1
FDD
6.5ms
3.8ms
2.8ms
2.3ms
2.0ms
Table 5. FDD with XTAL = 10MHz
The sample-clock DR(1:3)
The transmit current setting (TRC)
Handshake signals frequency
XTAL frequency
Supply voltage
The FDD is inversely proportional to the XTAL frequency and may
be calculated for other XTALs using the formula below:
FDDXTAL = (10 7 / XTAL) * FDD10MHz
The skew between the main TxD data channel and handshake
signals is 1 - 2 data bits as long as the maximum handshake datarate of 2kbps is respected. For handshake frequencies above
2kbps, the skew will be proportional to the handshake signal
frequency.
The sample-clock
The sample-clock selected by DR(1:3), see section headed DataRate Selection, determines the quantity of data transmitted over the
fiber link. The 'transmit' window opens once each frame and closes
when the time compress FIFO is empty. The 'receive' window is
aligned with the 'transmit' window of the far-end modem, and tracks
the 'transmit' window such that it closes on detection of the last data
bit. Clearly, the lower the sample-clock the smaller the active time
and the lower the power consumption.
LED considerations & Suppliers
Since LEDs from different suppliers may emit different
wavelengths, it is recommended that the LEDs in a communicating
pair of modems are obtained from the same supplier. The
ACS102A can support any wavelength LED or LASER.
Furthermore, the emission spectrum is a function of temperature,
so a temperature difference between the ends of a link reduces the
responsivity of the receiving LED, resulting in a reduction in the link
budget. Information is given in the suppliers’ data sheets. The
following manufacturers have components that will be tested with
the ACS102A and Acapella will be glad to assist with contact
names and addresses on request:
The transmit current setting
The formula given in section headed LED current control, relates to
the peak current delivered to the LED. The average current however
is very much lower. The DC balanced nature of data encoding means
the LED consumes current for approximately 50 % of the 'transmit'
window time. The average current delivered to the LED is therefore a
function of both the peak current and the duration of the 'transmit'
window.
MITEL
Acapella
GCA
Honeywell
Handshake signals frequency
Handshake data which is interleaved with the main data channel is
generated and written to the time compress FIFO each time a change
is detected on either RTS or DTR. The power consumption is lower
when the signals change at low frequency or are held at a DC level. It
is possible to limit the power consumption dedicated to the
handshake signals by limiting the frequency of operation using
HD(1:2) input pins. See section headed RS-232 Handshake Signals.
(e.g. 1A-212ST, 1A-212SMA)
(e.g. A-ST, A-SMA)
(e.g. 1A-212-ST-05, 1A-212-SM-02)
(e.g. HFE4214-013, HFE4404-013)
Power Supply Decoupling
XTAL frequency
The ACS102A contains a highly sensitive amplifier, capable of
responding to extremely low current levels. To exploit this sensitivity
it is important to reduce external noise to a low level compared to the
input signal from the LED or PIN. The modem should have an
independent power trace to the point where power enters the board.
The ACS102A uses CMOS technology and therefore the power
consumption is proportional to the frequency of switching.
Consequently, the effect of reducing the value of the XTAL alone will
result in lower power consumption. However, the current component
delivered to the LED and sourced from outputs such as RxD and HBT
are static and as such are independent of the XTAL frequency.
Figures 4 to 6 all show the recommended power supply decoupling.
The LED/PIN/LASER should be sited very close to the PINP, PINN,
LAN and LAP pins. A generous ground plane should be provided,
especially around the sensitive PINP, PINN, LAN and LAP pins. The
modem should be protected from EMI/RFI sources in the standard
ways.
Link Budgets
It is worth noting that a modem pair configured with an XTAL of
10MHz and a sample-clock of XTAL/40 will yield the same
performance as a modem pair configured with an XTAL of 5MHz and
a sample-clock of XTAL/20. However, the modem pair with the lower
value XTAL is likely to consume the higher power with a higher data
delay (see section headed Data delay and skew). This is because,
although the dynamic power has reduced, the higher sample-clock
leads to a much longer active time, a factor which dominates the
overall power calculation.
The link budget is the difference between the power coupled to the
fiber via the transmit LED and the power required to realise the
minimum input-amplifier current via the receive LED/PIN. The link
budget is normally specified in dB or dBm, and represents the
maximum attenuation allowed between communicating LEDs. The
budget is utilised in terms of the cable length, cable connectors and
splices. It usually includes an operating margin to allow for
degradation in LED performance. The power coupled to the cable, is
a function of the efficiency of the LED, the current applied to the LED
and the type of the fiber optic cable employed. The conversion
current produced by the reverse biased LED is a function of the LED
efficiency and the fiber type.
Current and Power Consumption
The average current consumption may be split into two components;
the dynamic component and the static component. The dynamic
6
Advanced Communications
ACS102A Data Sheet
PIN DESCRIPTION
PLCC44 Pin
TQFP44 Pin
Symbol
IO
PLCC44 Pin
Name
I
Power Supply
29
34
NSB
I
New Slice Bar Connect to GND.
Data Carrier
Detect
Modem control signal - LOW
when modems locked
30
35
GND
-
Ground
Ground Supply
31
-
NC
-
Not connected
Not connected
Request To
Send & Data
Channel 2 i/p
Modem control signal or
additional low frequency data
channel input
Capacitor
Integration
O
Ring indicator
output
An alternative data channel
which may be for the
propagation of the RS232 Ring
indicator signal.
Integrating capacitor is placed
between CNT and GND of
value 10nF-47nF with an XTAL
of 27-5Mhz
O
Data Set
Ready & Data
Channel 3 o/p
Modem control signal or
additional low frequency data
channel output
Laser monitor
A pull down current equal to
1/100 th of the Laser current.
Mode
Selection
2
7
GND
-
Ground
3
8
DCDB
O
I
6
7
11
12
RIO
DSR
LMN
O
8
13
RxD
O
Received Data
Received data
9
14
DR3
I
Data Rate
Select
The DR(1:3) inputs select the
Data Rates, see p2.
10
11
15
16
XLI
XLO
I
O
Oscillator
Crystal
Connect fundamental parallel
resonance crystal with padding
capacitors to GND
12
17
GND
-
Ground
Power Supply ground.
32
36
CNT
IO
-
37
GND
-
Ground
Ground Supply
33
34
38
39
PINN
PINP
I
I
PIN Cathode
PIN Anode
Connections to a PIN diode or
LASER monitor diode.
35
36
40
41
LAN
LAP
IO
IO
LED Cathode
Connections to LED or LASER
LED Anode
37
42
VA+
-
38
39
13
18
DP5
I
Mode
Selection
Selects operating mode for use
with PPLED, LED/PIN or
LASER/PIN.
14
19
VD+
-
+ve power
supply
Power Supply, 3.3-5.25 Volts
15
20
TxD
I
Transmit Data
Transmitted data
16
21
ERL
O
Error Detector
Indicates quality of line. If a
coding infringement is detected,
ERD goes High. Reset by
PORB to Low
I
Data Terminal
Ready/Data /
Channel 3 i/p
Modem contrrol signal or
additional low frequency data
channel input
O
Indicates power up and modem
'Heart beat'
Lock & power lock, pulses slowly when
locked, fast unlocked.
up indicator
17
18
22
23
DTR
HBT
Force low to put LASER in
constant transmit mode for
power adjustment. Leave
disconnected when using LEDs.
SETB
I
10
Description
32
DP1
5
Name
27
6
RTS
IO
Setup for
Laser testing
1
9
Sym
Description
Selects operating mode for use
with PPLED, LED/PIN or
LASER/PIN.
4
TQFP44 Pin
19
24
HD1
I
Handshake
Delay
Sets the Handshake bandwidth,
see p4
20
25
CTS
O
Clear To Send
& Data
Channel 2 o/p
Modem control signal or
additional low frequency data
channel output
21
26
HD2
I
Handshake
Delay
Sets the Handshake bandwidth,
see p4
22
27
PORB
I
Power-onReset
Will reset the device when
PORB = 0. Connect to an RC
circuit as in figure 4, so a reset
performed on power-up.
23
24
28
29
DR1
DR2
I
Data Rate
Select
The DR(1:3) inputs select the
Data Rates, see p3
25
26
28
30
31
33
DM3
DM2
DM1
I
Diagnostic
Modes
DM(1:3) input select for
Diagnostic Modes such as local
loopback and remote loopback
7
43
44
CTX
TRC
IO
+ve Supply
Power supply, 3.3-5.25 Volts
A 10 nF capacitor is connected
between this pin and ground for
Capacitor for LASER applications. It is used
Laser transmit in monitoring of the average
transmit power. Can be left
disconnected when using LEDs.
I
Transmit
Current
Defines transmit current to the
LED. Minimum and maximum
values are set by connecting
TRC to GND via a resistor,
value R defined by equation on
page 2.
An alternative data channel
which may be for the
propagation of the RS232 Ring
indicator signal.
40
1
RII
I
Ring indicator
input
41
2
DP4
I
Mode
Selection
Selects operating mode for use
with PPLED, LED/PIN or
LASER/PIN.
42
3
DP3
I
Mode
Selection
Selects operating mode for use
with PPLED, LED/PIN or
LASER/PIN.
43
4
VD+
-
+ve Supply
Power Supply, 3.3-5.5 Volts
44
5
DP2
I
Mode
Selection
Selects operating mode for use
with PPLED, LED/PIN or
LASER/PIN.
2
Advanced Communications
ACS102A Data Sheet
Single Fiber link
Link Budget Example (Rtrc set so LED launch current = 50mA peak)
Fiber type
Fiber size
Minimum Transmit Couple power to fiber (µW)
Minimum LED responsivity (A/W)
Minimum ACS102A sensitivity (nA)
Minimum input power to ACS102A amplifier (µW)
Link Budget (dB)
Average current consumption TxD = 19.2kbps (mA)
Average current consumption TxD = 64kbps (mA)
Plastic
1000 micron
1000
0.01
500
50
10
3.8
7.2
Glass
62.5micron
60
0.16
500
3.1
13
3.8
7.2
Glass
50 micron
40
0.16
500
3.1
11
3.8
7.2
Glass
62.5 micron
120
0.6
500
0.83
21
7
14
Glass
50 micron
80
0.6
500
0.83
19.8
7
7.6
Dual Fiber link optimised for performance
Link Budget Example (Rtrc set so LED launch current = 100mA peak)
2
Fiber type
Fiber size
Minimum Transmit Couple power to fiber (µW)
Minimum PIN responsivity (A/W)
Minimum ACS102A sensitivity (nA)
Minimum input power to ACS102A amplifier (µW)
Link Budget (dB)
Average current consumption TxD = 19.2kbps (mA)
Average current consumption TxD = 64kbps (mA)
Plastic
1000 micron
1000
0.1
500
5
23
7
14
Dual Fiber link optimised for low power & low cost optical components
Link Budget Example (Rtrc set so LED launch current = 12.5mA peak)
Fiber type
Fiber size
Minimum Transmit Couple power to fiber (µW)
Minimum PIN responsivity (A/W)
Minimum ACS102A sensitivity (nA)
Minimum input power to ACS102A amplifier (µW)
Link Budget (dB)
Average current consumption TxD = 19.2kbps (mA)
Average current consumption TxD = 64kbps (mA)
Plastic
1000 micron
125
0.1
500
5
13.9
2.2
3.4
Glass
62.5micron
13
0.6
500
0.83
12
2.2
3.4
Glass
50 micron
6.5
0.6
500
0.83
9
2.2
3.4
Calculating average current and power consumption
Average current
Iav (mA)
=
XTAL* 10 -7 (1.3 + 3*(A + U *H ) ) + Itrc (A + U * H) + Iout + Ihbt
=
Iav (mA) * V
Power
P (mW)
Terms used in current/power calculation:
XTAL
H
=
=
U
=
A
Note :
=
Crystal Oscillator Frequency, Hz
Handshake on
H=1 for handshakes active
H=0 for handshakes at DC level
Handshake constant
U = 0.001 when HD 2/1 = 0/0
U = 0.028 when HD 2/1 = 0/1
U = 0.014 when HD 2/1 = 1/0
U = 0.007 when HD 2/1 = 1/1
Active window constant
A = 0.022 when DR 3/2/1 = 0/1/1
A = 0.03
when DR 3/2/1 = 1/0/0
A = 0.045 when DR 3/2/1 = 1/0/1
A = 0.08
when DR 3/2/1 = 1/1/0
A = 0.11
when DR 3/2/1 = 1/1/1
Iout
=
Average current sourced
from digital outputs such
as (RxD,CTS,DSR,DCD)
Average current sourced
from HBT pin.
(see section HBT Status pin)
mA
Ihbt
=
Itrc
=
Peak Transmit current
set by TRC pin.
mA
V
=
Voltage supply to the ACS102 V
Power formula is only accurate
for voltage supply = 5 Volts
mA
An application note on power extraction from the RS232 lines is available from Acapella. This shows a typical example
circuit diagram for powering the ACS102A, the optics and all related circuitry from the RS232 data lines.
8
Advanced Communications
ACS102A Data Sheet
ELECTRICAL SPECIFICATION
Important Note: The "Absolute Maximum Ratings" are stress ratings only, and functional operation of the device at conditions other
than those indicated in the "Operating Conditions" sections of this specification are not implied. Exposure to the absolute maximum
ratings for an extended period may reduce the reliability or useful lifetime of the product.
Dynamic Characteristics (for specified operating conditions)
Absolute Maximum Ratings
Parameter
Parameter
Symbol
Min
Max
Units
XTAL
5
27
MHz
External clock (XTI)
High or Low time
fclp
40
-
60
%
RxD and TxD data rate
Function of DR(1:3) setting
fclf
DC
-
XTAL/150
Hz
Digital output - fall time
tf
-
-
100
ns
Digital output - rise time
tr
-
-
100
ns
Power consumption
(Note 2)
Pc
-
20
-
mW
Symbol
Min
Max
Units
VDD
-0.3
6.0
V
Crystal frequency
(XTI, XTO)
Input voltage
(non-supply pins)
Vin
GND - 0.3
VDD + 0.3
V
Input current
(except
LAN,LAP,PINN,PINP,CNT)
Iin
-
10.0
mA
Input current
( LAN,LAP,PINN,PINP,CNT)
Iin
-
1.0
mA
Tstor
-50
160
ºC
Power supply VD+ and VA+
(VDD = VD+ or VA+)
Storage temperature
Operating Conditions
Parameter
Symbol
Min
Typ
Max
Units
Power supply
(VA+ and VD+)
V+
3.3
5.0
5.25
V
Ambient temperature range
TA
-40
-
85
ºC
Note 2: See section on Calculating average current and power consumption
Matching Characteristics (for specified operating conditions)
Parameter
Static Digital Input Conditions (for specified operating conditions)
For Digital Input pins: TxD, RTS, DTR, PORB, RII, DP, DR(3:1), DM(3:1), HD(2:1).
Parameter
Typ
Symbol Min
Typ
Max
Units
Crystal tolerance
use parallel resonate crystal and
recommended padding capacitors
Ct
-250
0
250
ppm
Amplifier sensitivity input current
Irec
500
-
-
nA
Maximum amplifier input current
Imax
-
-
500
µA
Symbol
Min
Typ
Max
Units
Vin High
Vih
2.0
-
-
V
Rtrc placed between TRC and GND
Rtrc
0.8k
-
40k
Ω
Vin Low
Vil
-
-
0.8
V
Iled
Iin
-
0.2
5
µA
75
1.8
100
2.5
125
3.2
mA
Input current (High)
LED current
Rtrc = 1 kOhm
Rtrc = 40 kOhms
Input current (Low)
Iin
-
8
15
µA
Block Error Rate
BER
-
-
10-9
Single Fiber mode Parameters
Static Digital Output Conditions (for specified operating conditions)
For Digital Output pins: RxD, DSR, CTS, DCDB, ERRL, RIO, HBT.
Symbol
Min
Typ
Max
Units
LED capacitance with Vr =0
with Irec = 500 nA
with Irec = 1000 nA
Cl
-
-
50
100
pF
Vout Low
Vol
0
-
0.5
V
LED leakage with Vr = 1.4 V
Lleak
-
-
150
nA
Vout High
Voh
VDD-0.5
-
-
V
LED reverse bias
Vr
-
0
-
V
Isource and Isink (except HBT)
(Note 1)
Iout
4
-
-
mA
Cl
-
-
20
pF
Isource and Isink (HBT)
Iout
16
-
-
mA
Lleak
-
-
150
nA
Cl
-
-
50
pF
Vr
-
0
-
V
Parameter
Max load capacitance
Note 1:
Dual Fiber mode Parameters
PIN capacitance with Vr = 0
PIN leakage current
Pin reverse bias
Output source and sink currents should be kept to a minimum in order to achieve low power
consumption.
DTE
ACS102A
ACS102A
TxD
RxD
RTS
CTS
DTR
DSR
RII
RIO
One single fiber link
RxD
TxD
CTS
RTS
DSR
DTR
RIO
RII
Figure 2. Data and handshake signals transmitted over a single fiber.
9
DCE
2
Advanced Communications
ACS102A Data Sheet
PACKAGE INFORMATION
2
TQFP44
D1/E1
A
min
Dimensions in mm
A2
0.05
1.35
10.00
max
PLCC44
A1
min 17.40
0.15
1.45
D1/E1
D2/E2
D3/E3
16.51
14.99
Dimensions in mm
max 17.65
b
L
α
0.30
0.45
0°
0.45
0.75
7°
0.80
1.60
D/E
e
16.00
A
A1
A2
4.20
2.29
0.51
e
0.10
b
R
0.33
0.64
0.53
1.14
Copl.
1.27
4.57
3.04
Figure 3. Package Dimensions, PLCC44 & TQFP44
10
Copl
12.00
12.70
16.66
E/D
0.10
Advanced Communications
ACS102A Data Sheet
APPLICATION CIRCUITS
Basic RS-232 to Fiber Interface Circuit
ACS102A_PLCC
2
Figure 4. Typical application circuit for linking two PC Serial Ports via a Single Fiber Optic Cable using Ping-Pong LEDs
This diagram shows a PLCC44 package being used. The TQFP44 package option can be used with the same component layout.
ACS102A_PLCC
Figure 5. Basic Circuit for a Twin Fiber Link using LED and PIN.
11
Advanced Communications
ACS102A Data Sheet
ACS102A_PLCC
2
Figure 6. Basic Circuit for a Twin Fiber Link using LASER and PIN.
12
Advanced Communications
ACS102A Data Sheet
ORDERING INFORMATION
Device Code
Package
Temperature
ACS102A-TQ
TQFP44
-40 to 85°C(ambient)
ACS102A-PL
PLCC44
-40 to 85°C(ambient)
2
For additional information, contact the following:
Semtech Corporation Advanced Communications Products
E-Mail:
[email protected]
Internet:
http://www.semtech.com
USA:
652 Mitchell Road, Newbury Park, CA 91320-2289
Tel: +1 805 498 2111, Fax: +1 805 498 3804
FAR EAST: 11F, No. 46, Lane 11, Kuang Fu North Road, Taipei, Taiwan, R.O.C.
Tel: +886 2 2748 3380, Fax: +886 2 2748 3390
EUROPE:
Delta House, Chilworth Research Centre, Southampton, Hants, SO16 7NS, UK
Tel: +44 23 80 769008, Fax: +44 23 80 768612
ISO9001
CERTIFIED
Semtech reserves the right to change specifications on catalog devices without notice. © Copyright Semtech Corp 2000
13