MICRO-LINEAR ML4663

March 1997
ML4663
Single Chip 10BASE-FL Transceiver
GENERAL DESCRIPTION
FEATURES
The ML4663 single-chip 10BASE-FL transceiver integrates
both a ML4662 10BASE-FL transceiver with a ML4622
fiber optic data quantizer to implement a highly integrated
solution for 10BASE-FL transceivers. The ML4663 offers a
standard IEEE 802.3 AU interface that allows it to be
directly connected to industry standard manchester
encoder/decoder chips or an AUI connector.
■
The ML4663 provides a highly integrated solution that
requires a minimal number of external components, and is
compliant to the IEEE 802.3 10BASE-FL standard. The
transmitter offers a current drive output that directly drives
a fiber optic LED transmitter. The receiver offers a highly
stable fiber optic data quantizer capable of accepting
input signals as low as 2mVP-P with a 55dB dynamic
range.
■
The transmitter automatically inserts 1MHz signal during
idle time and removes this signal on reception. Low Light
is continuously monitored for both activity as well as
power level. Five LED status indicators monitor error
conditions as well as transmissions, receptions and
collisions.
BLOCK DIAGRAM
s
a
e
l
P
Tx+ 10
Tx– 11
e See
SQEN/JABD
5
6
6
4
L
M
■
■
■
■
■
■
Single chip solution for 10BASE-FL internal or external
Medium Attachment Units (MAUs)
Incorporates an AU interface
Highly stable data quantizer with 55dB input
dynamic range
Input sensitivity as low as 2mVP-P
Current driven fiber optic LED driver for accurate
launch power
Single +5 volt supply
No crystal or clock required
Five network status LED outputs
w
e
N
r
8 fo
s
n
g
i
Des
+5V
VCCTx
(+5V)
RTSET
17
AVCC
GND
12
20
27
FIBER OPTIC
LED
DRIVER
AUI
RECEIVER
18 TxOUT
15 XMT
Tx
SQUELCH
1MHz IDLE
SIGNAL
16 RCV
LED
DRIVERS
JABBER
1
CLSN
28 JAB
14 LMON
BIAS
SQE
RECEIVE SQUELCH
COL+ 2
AUI
DRIVER
COL– 3
10MHz GATED
OSCILLATOR
26 VIN+
AMP
25 VIN–
Tx
Rx+ 6
LOOPBACK
MUX
AUI
DRIVER
Rx– 7
CMP
Rx
21 VDC
∫
VREF
LINK DETECT
19
GND
9
VCC
(+5V)
13
8
RRSET LBDIS
24
AGND
22 VREF
23 VTHADJ
4
CTIMER
+5V
1
ML4663
PIN CONNECTION
2
COL+
CLSN
JAB
3
2
1
28
VIN+
COL–
4
AVCC
CTIMER
ML4663
28-Pin PLCC (Q28)
6
24
AGND
VTHADJ
22
VREF
VCC
9
21
VDC
Tx+
10
20
GND
Tx–
11
12
13
14 15
16
19
17 18
GND
TxOUT
23
8
VCCTx
7
XMT
Rx–
LBDIS
RCV
Rx+
VIN–
LMON
27 26
25
RRSET
5
RTSET
SQEN/JABD
ML4663
PIN DESCRIPTION
PIN
NAME
FUNCTION
PIN
NAME
FUNCTION
1
CLSN
Indicates that a collision is taking
place. Active low LED driver, open
collector. Event is extended with
internal timer for visibility.
15
XMT
Indicates that transmission is taking
place. Active low LED driver, open
collector. Event is extended with
internal timer for visibility.
2
3
COL+
COL–
Gated 10MHz oscillation used to
indicate a collision, SQE test, or
jabber. Balanced differential line
driver outputs that meet AUI
specifications.
16
RCV
Indicates that the transceiver is
receiving a frame from the optical
input. Active low LED driver, open
collector. Event is extended with
internal timer for visibility.
4
CTIMER
A capacitor from this pin to VCC
determines the Link Monitor
response time.
17
VCC Tx
+5 volt supply for fiber optic LED
driver.
18
TxOUT
Fiber optic LED driver output.
19
GND
Ground Reference.
20
GND
Ground Reference.
21
VDC
An external capacitor on this pin
integrates an error signal which
nulls the offset of the input
amplifier. If the DC feedback loop is
not being used, this pin should be
connected to VREF.
22
V REF
A 2.5V reference with respect to
GND.
23
VTHADJ
This input pin sets the link monitor
threshold.
24
AGND
Analog Filtered Ground.
25
VIN–
This input pin should be
capacitively coupled to the input
source or to filtered AVCC. (The
input resistance is approximately
1.3kΩ.)
26
VIN+
This input pin should be
capacitively coupled to the input
source or to filtered AVCC. (The
input resistance is approximately
1.3kΩ.)
27
AVCC
Analog Filtered +5 volts.
28
JAB
5
SQEN/JABD SQE Test Enable, Jabber Disable.
When tied low, SQE test is disabled,
when tied high SQE test is enabled.
When tied to 2.0V both SQE test and
Jabber are disabled.
6
7
Rx+
Rx–
8
LBDIS
Manchester encoded receive data
output to the local device. Balanced
differential line driver outputs that
meet AUI specifications.
Loopback Disable. When this pin is
tied to VCC , the AUI transmit pair
data is not looped back to the AUI
receive pair, and collision is disabled.
When this pin is tied to GND
(normal operation) or left floating, the
AUI transmit pair data is looped back
to the AUI receiver pair, except
during collision.
9
VCC
+5 volt power input.
10
11
Tx+
Tx–
Balanced differential line receiver
inputs that meet AUI specifications.
These inputs may be transformer or
capacitively coupled. The Tx input
pins are internally DC biased for AC
coupling.
12
RTSET
Sets the current driven output of the
transmitter.
13
RRSET
A 1% 61.9kΩ resistor tied from this
pin to VCC sets the biasing currents
for internal nodes.
14
LMON
Link Monitor “Low Light” LED status
output. This pin is pulled low when
the voltage on the VIN+, VIN– inputs
exceed the minimum threshold set by
the VTHADJ pin, and there are
transitions on VIN+, VIN– indicating
an idle signal or active data. If either
the voltage on the VIN+, VIN– inputs
fall below the minimum threshold or
transitions cease on VIN+, VIN–,
LMON will go high. Active low LED
driver, open collector.
Jabber network status LED. When in
the Jabber state, this pin will be low
and the transmitter will be disabled.
In the Jabber “OK” state this pin will
be high. Active low LED, open
collector.
3
ML4663
ABSOLUTE MAXIMUM RATINGS
Absolute maximum ratings are limits beyond which the
life of the integrated circuit may be impaired. All voltages
unless otherwise specified are measured with respect to
ground.
Power Supply Voltage Range
VCC ................................................................... GND –0.3 to 6V
Input Voltage Range
Digital Inputs
SQEN, LBDIS ....................... GND –0.3 to VCC +0.3V
Tx+, Tx–, VIN+, VIN– ............... GND –0.3 to VCC +0.3V
Input Current
RRSET, RTSET, JAB, CLSN, XMT, RCV, LMON ...... 60mA
Output Current
TxOUT ................................................................ 70mA
Junction Temperature .............................................. 150°C
Storage Temperature Range ...................... –65°C to 150°C
Lead Temperature (Soldering) .................................. 260°C
Thermal Resistance (θJA) ....................................... 68°C/W
OPERATING CONDITIONS
Supply Voltage (VCC) ........................................... 5V ± 5%
LED on Current ....................................................... 10mA
RRSET .......................................................... 61.9kΩ ± 1%
RTSET ............................................................. 115Ω ± 1%
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, TA = Operations Temperature Range, VCC = V CCTx = 5V ± 5% (Note 1)
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
ICC
Power Supply Current ICC:
While Transmitting
VCC = 5V, RTSET = 115Ω
(Note 2)
220
mA
VOL
LED Drivers: VOL
IOL = 10mA (Note 3)
0.8
V
IOUT
Transmit Peak Output Current
RTSET = 115Ω (Note 4)
VSQ
44
52
57
mA
Transmit Squelch Voltage Level
(Tx+, Tx–)
–300
–250
–200
mV
VDO
Differential Output Voltage
(Rx±, COL±)
±550
±1200
mV
VCM
Common Mode Output Voltage
(Rx±, COL±)
VDOO
Differential Output Voltage
Imbalance (Rx±, COL±)
VSQE
SQE/JABD
VLBTH
4
PARAMETER
LBDIS Threshold
4.0
SQE Test Disable
Both Disabled
Both Enabled
Disabled
Enabled
1.5
VCC – 0.5
V
±40
mV
0.3
VCC – 2
V
V
V
VCC – 0.1
1
V
V
VTXCM
Common Mode Voltage
(Tx+, Tx–)
3.5
V
VINCM
Common Mode Voltage
(VIN+, VIN–)
1.65
V
VREF
Reference Voltage
IREF
VREF Output Source Current
AV
Amplifier Gain
VISR
Input Signal Range
2.30
2.45
2.60
V
5
mA
100
2
V/V
1600
mVP–P
ML4663
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, TA = Operations Temperature Range, VCC = VCCTx = 5V ± 5% (Note 1)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
2.7
V
VTHADJ
External Voltage at VTHADJ
to Set VTH
VOFF
Input Offset
VDC = VREF (DC loop inactive)
3
mV
VN
Input Referred Noise
50MHz BW
25
µV
RIN
Input Resistance
VIN+, VIN–
ITH
Input Bias Current of VTHADJ
VTH
Input Threshold Voltage
H
Hysteresis
0.5
VTHADJ = VREF (Note 5)
0.8
1.3
2.0
kΩ
–200
10
+200
µA
5
6
7
mVP–P
20
%
AC ELECTRICAL CHARACTERISTICS
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS
Transmit
FTXIDF
Transmit Idle Frequency
0.85
1.25
MHz
PTXDC
Transmit Idle Duty Cycle
45
55
%
tTXNPW
Transmit Turn-On Pulse Width
tTXODY
Transmit Turn-On Delay
200
ns
tTXLP
Transmit Loopback Start-up Delay
500
ns
tTXFPW
Transmit Turn-Off Pulse Width
tTXSOI
Transmit Turn-Off Start of Idle
tTXSDY
Transmit Steady State Propagation Delay
tTXJ
Transmit Jitter into 31Ω Load
20
ns
180
400
15
ns
2100
ns
50
ns
±1.5
ns
4.5
MHz
285
ns
Receive
FRXSFT
Receive Squelch Frequency Threshold
2.51
tRXODY
Receive Turn-On Delay
tRXFX
Last Bit Received to Slow Decay Output
tRXSDY
Receive Steady State Propagation Delay
tRXJ
Receive Jitter
tAR
Differential Output Rise Time 20% to 80% (Rx±, COL±)
4
ns
tAF
Differential Output Fall Time 20% to 80% (Rx±, COL±)
4
ns
230
300
15
ns
50
ns
±1.5
ns
5
ML4663
AC ELECTRICAL CHARACTERISTICS
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS
Collision
tCPSQE
Collision Present to SQE Assert
0
350
ns
tSQEXR
Time for SQE to Deactivate After Collision
0
700
ns
FCLF
Collision Frequency
8.5
11.5
MHz
PCLPDC
Collision Pulse Duty Cycle
40
60
%
tSQEDY
SQE Test Delay (Tx Inactive to SQE)
0.6
1.6
µs
tSQETD
SQE Test Duration
0.5
1.0
1.5
µs
50
Jabber and LED Timing
tJAD
Jabber Activation Delay
20
70
150
ms
tJRT
Jabber Reset Unjab Time
250
450
750
ms
tJSQE
Delay from Outputs Disabled to Collision Oscillator On
tLED
RCV, CLSN, XMT On Time
8
16
32
ms
tLLPH
Low Light Present to LMON High
3
5
10
µs
tLLCL
Low Light Present to LMON Low
250
750
ms
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
6
Limits are guaranteed by 100% testing, sampling, or correlation with worst-case test conditions.
This does not include the current from the AUI pull-down resistors, or LED status outputs.
LED drivers can sink up to 20mA, but VOL will be higher.
Does not include pre-bias current for fiber optic LED which would typically be 3mA.
Threshold for switching from Link Fail to Link Pass (Low Light).
100
ns
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
AULRX–
AULRX+
AULPWR+
AULPWR–
AULCP–
AULCP+
AULTX–
AULTX+
CHASSIS REF
+5V
33µ
+
+5V 3KΩ
8
COL–
0.1
0.1µ
IN
VR1
D1
RP1
510Ω
VCC
9
Q1
OUT
LM340
GND
5 SQE
360Ω
6 Rx+
7
Rx–
360Ω
39Ω
10 Tx+
11
Tx–
39Ω
0.1µF
5KΩ
9
10
7
13
12
D1
360Ω
360Ω
15
2 COL+
16
5
D0
4
2
CI
1
3
+
4.7µ
19, 20
+
ML4663
ALL
510Ω
RP1
15 16 1
28 14
XMT RCV CLSN JAB LMON
0.1µ
22
25
26
21
4
8
17
4.7µH
0.1
0.05
4.7 + 0.1
+VRF
–VRF
4.7µH
27
24
VTHADJ 23
VREF
VIN–
VIN+
VDC
CTIMER
LBDIS
TxVCC
TxOUT
18
115Ω
13
12
RRSET RTSET
61.9k
–VRF
+VRF
+5V
0.01
–VRF
+VRF
–VRF
0.01
1k
R17
10Ω
6
+VRF
FIBER OPTIC
TRANSMITTER
HP HFBR1414
OR
OPTEK
OPC1414
–VRF
7
3
–VRF
FIBER OPTIC CABLE
FIBER OPTIC CABLE
0.1µF
0.1µF
FIBER OPTIC RCVR
4 HP HFBR2416
OR
5
OPTEK
OPC2416
8
1
2
3
2,6,7
+5V
ML4663
HP HFBR1414
OR
OPTEK
OPC1414
Figure 1. ML4663 Schematic Diagram
7
ML4663
SYSTEM DESCRIPTION
Figure 1 shows a schematic diagram of the ML4663 in an
internal or external 10BASE-FL MAU. On one side of the
transceiver is the AU interface and the other is the fiber
optic interface. The AU interface is AC coupled when
used in an external transceiver or an internal transceiver.
The AU interface for an external transceiver includes
isolation transformers, some biasing resistors, and a
voltage regulator for power.
The fiber optic side of the transceiver requires an external
fiber optic transmitter and fiber optic receiver. The
transmitter uses a current driven output that directly drives
the fiber optic transmitter. The receive side of the
transceiver accepts the data after passing through a fiber
optic receiver, which consists of a module containing a
pin diode and a transimpedance amplifier.
AU INTERFACE
The AU interface consists of 3 pairs of signals: DO, CI and
DI (Figure 1). The DO pair contains transmit data from the
DTE which is received by the transceiver and sent out
onto the fiber optic cable. The DI pair contains valid data
that has been either received from the fiber optic cable or
looped back from the DO, and output through the DI pair
to the DTE. The CI pair indicates whether a collision has
occurred. It is an output that oscillates at 10MHz if a
collision, Jabber or SQE Test has taken place, otherwise it
remains idle.
When the transceiver is external, these three pairs are AC
coupled through isolation transformers, while an internal
transceiver may be capacitively coupled. Tx+, Tx– is
internally DC biased (shifted up in voltage) for the proper
common mode input voltage.
The two 39Ω 1% resistors (or one 78Ω 1% resistor) tied to
the Tx+ and Tx– pins will provide the proper termination.
The CI and DI pair, which are output from the transceiver
to the AUI cable, require 360Ω pull down resistors when
terminated with a 78Ω load. However on a DTE card, CI
and DI do not need 78Ω terminating resistors. This also
means that the pull down resistors on CI and DI can be
1kΩ or greater depending upon the particular Manchester
encoder/decoder chip used. Using higher value pull down
resistors as in a DTE card will save power. Refer to
Application Note 13 for a more detailed explanation of
the AUI pull-down resistors.
The AUI drivers are capable of driving the full 50 meters
of cable length and have a rise and fall time of typically
4ns. In the idle state, the outputs go to the same voltage to
prevent DC standing current in the isolation transformers.
TRANSMISSION
The transmit function consists of detecting the presence of
data from the AUI DO input (Tx+, Tx–) and driving that
data onto the fiber optic LED transmitter. A positive signal
on the Tx+ lead relative to the Tx– lead of the DO circuit
will result in no current, hence the fiber optic LED is in a
low light condition. When Tx+ is more negative than Tx–,
the ML4663 will sink current into the chip and the fiber
optic LED will light up.
8
Before data will be transmitted onto the fiber optic cable
from the AUI interface, it must exceed the squelch
requirements for the DO pair. The Tx squelch circuit
serves the function of preventing any noise from being
transmitted onto the fiber. This circuit rejects signals with
pulse widths less than typically 20ns (negative going), or
with levels less than –250mV. Once Tx squelch circuit has
unsquelched, it looks for the start of idle signal to turn on
the squelch circuit again. The transmitter turns on the
squelch again when it receives an input signal at Tx+,
Tx– that is more positive than –250mV for more than
approximately 180ns.
At the start of a packet transmission, no more than 2 bits
are received from the DO circuit, and are not transmitted
onto the fiber optic cable. The difference between start-up
delays (bit loss plus steady-state propagation delay) for
any two packets that are separated by 9.6µs or less will
not exceed 200ns.
FIBER OPTIC LED DRIVER
The output stage of the transmitter is a current mode
switch which develops the output light by sinking current
through the LED into the TxOUT pin. Once the current
requirement for the LED is determined, the RTSET resistor
is selected. The following equation is used to select the
correct RTSET resistor:


RTSET=  52mA  115Ω
 IOUT 
The transmitter enters the idle state when it detects start of
idle on Tx+ and Tx– input pins. After detection, the
transmitter switches to a 1MHz output idle signal.
The output current is switched through the TxOUT pin
during the on cycle and the VCC Tx pin during the off cycle
as shown in figure 2. Since the sum of the current in these
two pins is constant, VCC Tx should be connected as close
as possible to the VCC connection for the LED.
If not driving an optical LED directly, a differential output
can be generated by tying resistors from VCCTx and
TxOUT to VCC as shown in figure 3. The minimum
voltage on these two pins should not be less than
VCC – 2V.
VCCTx
TxOUT
IOUT
Figure 2. Fiber Optic LED Driver Structure.
ML4663
SQE TEST FUNCTION (SIGNAL QUALITY ERROR)
VCC
51Ω
51Ω
51Ω
RTSET = 560Ω
IOUT = 15.9mA
ECL
VCCTx
TxOUT
Figure 3. Converting Optical LED Driver Output to
Differential ECL.
RECEPTION
The input to the transceiver comes from a fiber optic
receiver (Figure 1). At the start of packet reception no
more than 2.7 bits are received from the fiber cable, and
are not transmitted onto the DI circuit. The receive
squelch will reject frequencies lower than 2.51MHz.
While in the unsquelch state, the receive squelch circuit
looks for the start of idle signal at the end of the packet.
Start of idle occurs when the input signal remains idle for
more than 160ns. When start of idle is detected, the
receive squelch circuit returns to the squelch state and the
start of idle signal is output on the DI circuit (Rx+, Rx–).
COLLISION
Whenever the receiver and the transmitter are active at
the same time the chip will activate the collision output,
except when loopback is disabled (LBDIS = VCC ). The
collision output is a differential square wave matching the
AUI specifications and capable of driving a 78Ω load. The
frequency of the square wave is 10MHz ± 15% with a 60/
40 to 40/60 duty cycle. The collision oscillator also is
activated during SQE Test and Jabber.
LOOPBACK
The loopback function emulates a 10BASE-T transceiver
whereby the transmit data sent by the DTE is looped back
over the AUI receive pair. Some LAN controllers use this
loopback information to determine whether a MAU is
connected by monitoring the carrier sense while
transmitting. The software can use this loopback
information to determine whether a MAU is connected to
the DTE by checking the status of carrier sense after each
packet transmission.
When data is received by the chip while transmitting, a
collision condition exits. This will cause the collision
oscillator to turn on and the data on the DI pair will
follow VIN+, VIN–. After a collision is detected, the
collision oscillator will remain on until either DO or
VIN+, VIN– go idle.
Loopback can be disabled by strapping LBDIS to VCC.
In this mode the chip operates as a full duplex transmitter
and receiver, and collision detection is disabled. A
loopback through the transceiver can be accomplished by
tying the fiber transmitter to the receiver.
The SQE test function allows the DTE to determine
whether the collision detect circuitry is functional. After
each transmission, during the inter packet gap time, the
collision oscillator will be activated for typically 1µs. The
SQE test will not be activated if the chip is in the low light
state, or the jabber on state.
For SQE to operate, the SQEN pin must be tied to VCC .
This allows the MAU to be interfaced to a DTE. The SQE
test can be disabled by tying the SQEN pin to ground, for
a repeater interface.
JABBER FUNCTION REQUIREMENTS
The Jabber function prevents a babbling transmitter from
bringing down the network. Within the transceiver is a
Jabber timer that starts at the beginning of each
transmission and resets at the end of each transmission. If
the transmission last longer than 20ms the Jabber logic
disables the transmitter and turns on the collision signal
COL+, COL–. When Tx+ and Tx– finally go idle, a second
timer measures 0.5 seconds of idle time before the
transmitter is enabled and collision is turned off. Even
though the transmitter is disabled during Jabber, the 1MHz
idle signal is still transmitted.
LED DRIVERS
The ML4663 has five LED drivers. The LED driver pins are
active low, and the LEDs are normally off (except for
LMON). The LEDs are tied to their respective pins through
a 500Ω resistor to 5V.
The XMT, RCV and CLSN pins have pulse stretchers on
them which enables the LEDs to be visible. When
transmission or reception occurs, the LED XMT, RCV or
CLSN status pins will activate low for several
milliseconds. If another transmit, receive or collision
conditions occurs before the timer expires, the LED timer
will reset and restart the timing. Therefore rapid events
will leave the LEDs continuously on. The JAB and LMON
LEDs do not have pulse stretchers on them since their
conditions occur long enough for the eye to see.
LOW LIGHT CONDITION
The LMON LED output is used to indicate a low light
condition. LMON is activated low when both the receive
power exceeds the Link Monitor threshold and there are
transitions on VIN+, VIN– less than 3µs apart. If either one
of these conditions do not exist, LMON will go high.
INPUT AMPLIFIER
The VIN+, VIN– input signal is fed into a limiting amplifier
with a gain of about 100 and input resistance of 1.3kΩ.
Maximum sensitivity is achieved through the use of a DC
restoration feedback loop and AC coupling the input.
When AC coupled, the input DC bias voltage is set by an
on-chip network at about 1.7V. These coupling capacitors,
in conjunction with the input impedance of the amplifier,
establish a high pass filter with 3dB corner frequency, fL,
at
1
fL =
(1)
2π1300C
9
ML4663
Since the amplifier has a differential input, two capacitors
of equal value are required. If the signal driving the input
is single ended, one of the coupling capacitors can be tied
to AVCC (Figure 1).
The internal amplifier has a lowpass filter built-in to band
limit the input signal which in turn will improve the signal
to noise ratio.
Although the input is AC coupled, the offset voltage within
the amplifier will be present at the amplifier’s output. This
is represented by VOS in Figure 4. In order to reduce this
error a DC feedback loop is incorporated. This negative
feedback loop nulls the offset voltage, forcing VOS to be
zero. Although the capacitor on V DC is non-critical, the
pole it creates can effect the stability of the feedback loop.
To avoid stability problems, the value of this capacitor
should be at least 10 times larger than the input coupling
capacitors.
VOUT+
VOS
VOUT–
Figure 4.
The comparator is a high-speed, differential zero crossing
detector that slices and accurately digitizes the receive
signal. The output of the comparator is fed in parallel into
both the receive squelch circuit and the loopback MUX.
LINK DETECT CIRCUIT AND LOW LIGHT
The link detect circuit monitors the input signal and
determines when the input falls below a preset voltage
level. When the input falls below a preset voltage, the
ML4663 goes into the Low Light state. In the Low Light
state the transmitter is disabled, but continues sending the
1MHz idle signal, the loopback is disabled, the receiver is
disabled, and the LMON LED pin goes to high shutting off
the LMON LED. To return to the Link Pass state, the
optical receiver power must be 20% higher than the shutoff state. This built-in hysteresis adds stability to the Link
Monitor circuit. Once the receiver power threshold is
exceeded, the ML4663 waits 250ms to 750ms, then
checks to see that Tx+. Tx– is idle and no data is being
received before re-enabling the transmitter, receiver,
loopback circuit, and lighting up the LMON LED.
The VTHADJ pin is used to adjust the sensitivity of the
receiver. The ML4663 is capable of exceeding the
10BASE-FL specifications for sensitivity. The sensitivity is
dependent on the layout of the PC board. A good low
noise layout will exceed the 10BASE-FL specifications,
while a poor layout will fail to meet the sensitivity and
BER spec.
The threshold generator shifts the reference voltage at
VTHADJ through a circuit which has a temperature
coefficient matching that of the limiting amplifier. The
relationship between the VTHADJ and the VTH (the peak to
peak input threshold) is:
VTHADJ = 408VTH
In a 10BASE-FL receiver there must be less than 1 x
bit errors at a receive power level of –32.5dBm average.
One procedure to determine the sensitivity of a receiver is
to start at the lowest optical power level and gradually
increase the optical power until the BER is met. In this
case the Link Detect circuit must not disable the receiver
(i.e. VTHADJ should be tied to Ground). Once the
sensitivity of the receiver is determined, VTHADJ can be set
just above the power level that meets the BER
specification. This way the receiver will shut-off before the
BER is exceeded.
For 10BASE-FL VTHADJ can be tied directly to VREF.
However if greater sensitivity is required the circuit in
figure 5 can be used to adjust the VTHADJ voltage. Even if
VREF is tied to VTHADJ, it is a good idea to layout a board
with these two resistors available. This will allow potential
future adjustments without board revisions.
The response time of the Link Detect circuit is set by the
CTIMER pin. Starting from the link off state the link can be
switched on if the input exceeds the set threshold for a
time given by:
T=
CTIMER × 0.7V
700µA
(3)
To switch the link from on to off, the above time will be
doubled. A value of 0.05µF will meet to 10BASE-FL
specifications.
VREF
R1
R2
VTHADJ
REF
THRESH
GEN
Figure 5.
10
(2)
10–10
ML4663
TIMING DIAGRAMS
tTXNPW
Tx+
VALID DATA
Tx–
tTXODY
tTXSDY
1
FTXIDF
tTXFPW
tTXSOI
IDLE
TxOUT
VALID DATA
IDLE
tTXLP
Rx+
VALID DATA
Rx–
Figure 6. Transmit and Loopback Timing
VIN+
VALID
VIN–
DATA
tROXDY
tRXSDY
tAR
tRXFX
tAF
Rx+
VALID
DATA
Rx–
Figure 7. Receive Timing
Tx+
VALID
Tx–
DATA
VIN+
VALID
VIN–
DATA
tCPSQE
COL+
CS0
COL–
Rx+
Tx
Tx
Rx
Rx
Rx
Rx–
Figure 8. Collision Timing
11
ML4663
TIMING DIAGRAMS
VIN+
VALID
DATA
VALID
DATA
VIN–
Tx+
Tx–
tCPSQE
COL+
CS0
COL–
Figure 9. Collision Timing
VIN+
VIN–
Tx+
VALID
Tx–
DATA
tSQEXR
COL+
CS0
COL–
Rx+
Rx–
Rx
Rx
Rx
Tx
Tx
Tx
Figure 10. Collision Timing
Tx+
Tx–
VIN+
VALID
VIN–
DATA
tSQEXR
COL+
CS0
COL–
Rx+
Rx–
RxIN
RxIN
RxIN
RxIN
Figure 11. Collision Timing
12
RxIN
ML4663
TIMING DIAGRAMS
1
FCLF
COL+
COL–
Figure 12. Collision Timing
Tx+
Tx–
VALID DATA
tSQEDY
tSQETD
COL+
CS0
COL–
Figure 13. SQE Timing
Tx+
VALID
DATA
Tx –
tJAD
TxOUT
tJRT
VALID
DATA
tJSQE
COL+
CS0
COL–
Figure 14. Jabber Timing
Tx+
Tx–
tLED
XMT
Figure 15. LED Timing
13
ML4663
TIMING DIAGRAMS
VIN+
VIN–
tLED
RCV
Figure 16. LED Timing
VIN+
VIN–
LMON
tLLPH
tLLCL
Figure 17. LED Timing
14
ML4663
PHYSICAL DIMENSIONS inches (millimeters)
Package: Q28
28-Pin PLCC
0.485 - 0.495
(12.32 - 12.57)
0.042 - 0.056
(1.07 - 1.42)
0.450 - 0.456
(11.43 - 11.58)
0.025 - 0.045
(0.63 - 1.14)
(RADIUS)
1
0.042 - 0.048
(1.07 - 1.22)
PIN 1 ID
8
22
0.300 BSC
(7.62 BSC)
0.450 - 0.456 0.485 - 0.495
(11.43 - 11.58) (12.32 - 12.57)
0.390 - 0.430
(9.90 - 10.92)
15
0.009 - 0.011
(0.23 - 0.28)
0.050 BSC
(1.27 BSC)
0.026 - 0.032
(0.66 - 0.81)
0.013 - 0.021
(0.33 - 0.53)
0.165 - 0.180
(4.06 - 4.57)
0.148 - 0.156
(3.76 - 3.96)
0.099 - 0.110
(2.51 - 2.79)
SEATING PLANE
ORDERING INFORMATION
PART NUMBER
TEMPERATURE
PACKAGE
ML4663CQ
0°C to 70°C
28-Pin PLCC (Q28)
© Micro Linear 1997
is a registered trademark of Micro Linear Corporation
Products described in this document may be covered by one or more of the following patents, U.S.: 4,897,611; 4,964,026; 5,027,116; 5,281,862; 5,283,483; 5,418,502; 5,508,570; 5,510,727; 5,523,940;
5,546,017; 5,559,470; 5,565,761; 5,592,128; 5,594,376; Japan: 2598946. Other patents are pending.
Micro Linear reserves the right to make changes to any product herein to improve reliability, function or design.
Micro Linear does not assume any liability arising out of the application or use of any product described herein,
neither does it convey any license under its patent right nor the rights of others. The circuits contained in this
data sheet are offered as possible applications only. Micro Linear makes no warranties or representations as to
whether the illustrated circuits infringe any intellectual property rights of others, and will accept no responsibility
or liability for use of any application herein. The customer is urged to consult with appropriate legal counsel
before deciding on a particular application.
15
2092 Concourse Drive
San Jose, CA 95131
Tel: 408/433-5200
Fax: 408/432-0295
DS4663-01