MICRO-LINEAR ML6651CH

ADVANCED
Information
ML6651 Auto-Negotiating Media Converter
GENERAL DESCRIPTION
The ML6651 converts signals transmitted between twisted
pair and fiber optic Ethernet technologies. It supports
conversion between 10BASE-T and 10BASE-FL, between
100BASE-TX and 100BASE-FX/SX, and between FLP (fast
link pulse) bursts and FLNP (fiber link negotiation pulse)
bursts. Either 850nm or 1300nm laser optics can be used
for both 10 and 100 Mb/second operating data rates while
fully auto-negotiating for speed and duplex mode
communication. One or both of the fiber optic and
twisted pair interfaces can be set to interface with
industry standard 1x9 fiber optic PMD modules, using
PECL or LVPECL compatible modes.
FEATURES
■ Complete implementation of fiber optic and twisted
pair media interface
■ ISO/IEC 8802.3, IEEE 802.3 and TIA/EIA-785
compliance, including full auto-negotiation for twisted
pair and fiber optic media
■ 850nm, 1300nm and 1x9 PMD modules
■ Supports 1:1 receiver/transmitter transformer ratio for
twisted pair
■ Low latency 10Mb/s path
■ Integrated voltage and current references
■ Integrated twisted pair output wave shaping eliminate
external filtering
■ Integrated twisted pair 10BASE-T input filter and
100BASE-TX equalizer with baseline wander correction
circuit
ADVANCED DATASHEET
September 2000
ADVANCED
ML6651
TABLE OF CONTENTS
General Description ......................................................................................................................................................... 1
Features ........................................................................................................................................................................... 1
Warranty Information ....................................................................................................................................................... 2
Block Diagram ................................................................................................................................................................. 3
Pin Configuration ............................................................................................................................................................. 4
Pin Descriptions ............................................................................................................................................................... 4
Physical Dimensions ...................................................................................................................................................... 10
Order Information .......................................................................................................................................................... 10
WARRANTY
Micro Linear makes no representations or warranties with respect to the accuracy, utility, or completeness of the contents of
this publication and reserves the right to make changes to specifications and product descriptions at any time without notice.
No license, express or implied, by estoppel or otherwise, to any patents or other intellectual property rights is granted by this
document. The circuits contained in this document are offered as possible applications only. Particular uses or applications
may invalidate some of the specifications and/or product descriptions contained herein. The customer is urged to perform its
own engineering review before deciding on a particular application. Micro Linear assumes no liability whatsoever, and
disclaims any express or implied warranty, relating to sale and/or use of Micro Linear products including liability or warranties
relating to merchantability, fitness for a particular purpose, or infringement of any intellectual property right. Micro Linear
products are not designed for use in medical, life saving, or life sustaining applications.
© Micro Linear 2000.
property of their respective owners.
is a registered trademark of Micro Linear Corporation. All other trademarks are the
Products described herein may be covered by one or more of the following U.S. patents: 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;
5,652,479; 5,661,427; 5,663,874; 5,672,959; 5,689,167; 5,714,897; 5,717,798; 5,742,151; 5,747,977; 5,754,012; 5,757,174;
5,767,653; 5,777,514; 5,793,168; 5,798,635; 5,804,950; 5,808,455; 5,811,999; 5,818,207; 5,818,669; 5,825,165; 5,825,223;
5,838,723; 5.844,378; 5,844,941. Japan: 2,598,946; 2,619,299; 2,704,176; 2,821,714. Other patents are pending.
2
Advanced Datasheet
September 2000
ADVANCED
ML6651
BLOCK DIAGRAM
35
TPOUTP
1
TPOUTN
3
38
41
17
15
2
33
32
18
11
39
33 FOINP
Auto Negation Processing
Twisted Pair
23
Fiber Optic
32 FOINN
10Mb/s Processing
RTTP
38
TPINP
10
TPINN
11
/ PECL Output
Twisted Pair
30 CQOS
100Base-TX
Descrambler
100Mb/s Clock and Data
Recovery
100Mb/s Clock and Data
Recovery
100Base-TX
Descrambler
29 SDFO
/ PECL Input
39 SDTH
21 IOUT
Fiber Optic
22 IOUT
10Mb/s Processing
REQSD
37
/ PECLOutput
/ PECL Input
36 RTOP
Auto Negation Processing
18
September 2000
GNDT
Advanced Datasheet
GNDQ
GNDB
2 9 12 15 19 20 23 26 28 31 34 35
GNDL
VCCL
VCCFC
GNDFC
VCCQ
16
VCCE
GNDE
GNDD
VCCD
17
MDIO
Trimming
MDC
23 25
DUPLI|EX
6
AD10
5
Management
Interface
SPEED
4
AD32
TPINSPD
PECLTP
TPANDT
PECLQU
FOINSPD
40 24 14 13 7 8
TPOUTOFF
41
FOOUTOFF
43
BCKLINK
42
PWRDWN
44
AD4LIW
Configuration
and Control Logic
STATUS LED
& Backup Link
FOANDT
REFCLK
3
ADVANCED
ML6651
PIN CONFIGURATION
FOANDT
TPANDT
FOINSPD
TPINSPD
BCKPLINK
SDTH
RTTP
REQSD
RTOP
GNDB
GNDQ
ML6651
44-Pin TQFP (H44-10)
44
43
42
41
40
39
38
37
36
35
34
33
30
CQOS
AD32
5
29
SDFO
AD10
6
28
GNDFC
PECLTP
7
27
SPEED
PECLQU
8
26
VCCFC
VCCE
9
25
DUPULEX
TPINP
10
24
PWRDWN
TPINN
11
GNDE
12
13
14
15
16
17
18
19
20
21
23
22
IOUT
4
IOUT
VCCQ
AD4LIW
GNDL
31
VCCD
3
REFCLOCK
FOINN
TPOUTN
MDC
32
MDIO
2
GNDD
FOINP
GNDT
TPOUTOFF
1
FOOUTOFF
TPOUTP
VCCL
TOP VIEW
PIN DESCRIPTIONS
Pin # Signal Name
1
TPOUTP
3
4
TPOUTN
Description
Two operating modes are available for these pins and are selected with the configuration pin
PECLTP (pin 7) or the configuration bit LVPECLTP (bit 30.3)
Twisted Pair Interface Mode:
Transmit twisted pair positive and complementary outputs. These outputs form a differential
current output pair that drives MLT-3 waveforms into the network coupling transformer during
100 Mb/s mode, Manchester encoded 10BASE-T data or NLPs during 10 Mb/s mode, and FLP
Bursts during Auto-Negotiation.
The polarity of TPOUTP/N is such that during the transmission of a linkpulse, all the current goes
into TPOUTN than it into TPOUTP. Since there is a resistor to VCC from each of the 2 pins, the
differential voltage V(TPOUTP)-V(TPOUTN) is positive during the linkpulse.
LVPECL/PECL Compatible Interface Mode:
LVPECL or PECL interface positive and complementary outputs. These outputs form a differential
current output pair that drives NRZI encoded 100BASE-FX or 100BASE-SX symbols during 100
Mb/s mode, Manchester encoded 10BASE-FL data or OPT_IDL during 10 Mb/s mode, and FLNP
Bursts during Auto-Negotiation. TPOUTP and TPOUTN are loaded with external resistors to VCC
and AC coupled to the inputs of a 1x9 fiber optic PMD module. A resistor network may be
needed to setup the common mode voltage at the input pins of the PMD module.
Advanced Datasheet
September 2000
ADVANCED
ML6651
PIN DESCRIPTIONS (continued)
Pin # Signal Name
Description
38
RTTP
Twisted pair or LVPECL/PECL compatible driver bias resistor. An external resistor connected
between RTTP and ground sets a constant bias current for the differential output driver circuitry.
These output currents depend on the operating mode.
The recommended external component values are:
Twisted pair mode:
2KW, 1 %, between RTTP and ground.
50W, 1 %, between TPOUTP and VCC
50W, 1 %, between TPOUTN and VCC
LVPECL/PECL compatible mode:
2KW, 1 %, between RTTP and ground.
62W, 1 %, between TPOUTP and VCC
62W, 1 %, between TPOUTN and VCC
Also AC couple to the PMD inputs
10
TPINP
Two operating modes are available for these pins and are selected with the configuration pin
PECLTP or the configuration bit LVPECLTP (bit 30.3).
11
TPINN
Twisted Pair Interface Mode:
Receive twisted pair positive and complementary inputs. These inputs form a differential input
pair that receives 100BASE-TX, FLP Burst, or 10BASE-T signal from the network. The common
mode voltage is set internally and the input impedance is about 10KW.
LVPECL/PECL Compatible Interface Mode:
LVPECL or PECL compatible interface positive and complementary inputs. These inputs form a
differential input pair that receives 100BASE-FX, 100BASE-SX, FLNP Bursts, or 10BASE-FL signal
from a fiber optic PMD. The PMD outputs are AC coupled to these inputs with .1mF capacitors.
The common mode voltage is set internally with resistors of about 1KW from each input pin to an
on-chip voltage reference. The positive output of the PMD (high during the high-light state) must
connect to TPINP and the complementary output of the PMD must connect to TPIN
37
REQSD
Twisted Pair Interface Mode:
Equalizer bias resistor pin. An external resistor connected between this pin and ground sets
internal currents that control the receiver’s adaptive equalizer transfer function. The voltage at
this pin is PTAT. It’s nominal value is 1.2V and it’s range is .9V to 1.5V. The recommended resistor
value is 5KW, 1 %
LVPECL/PECL Compatible Interface Mode:
This input pin is connected to the Signal Detect (SD) output of a fiber optic PMD module. The
voltage level at this pin is compared to the voltage level at pin SDTH to determine the logic
value. If it is lower, then the input at TPINP/TPINN is rejected. If it is higher, then the input at
TPINP/TPINN is passed to the internal circuits.
39
SDTH
The voltage at this pin is a single ended LVPECL/PECL reference. Refer to description of SDFO
and REQSD pins.
This pin is not used if neither the TPINP/TPINN interface, nor the FOINP/FOINN are setup for
LVPECL/PECL compatible mode. In such a case, the SDTH pin must be connected to any
potential between VCC and Ground.
21
IOUT
2 operating modes are available for these pins and are selected with the configuration pin
“PECL_QU” or the configuration bit “LVPECLQU” (bit 30.7).
September 2000
Advanced Datasheet
5
ADVANCED
ML6651
PIN DESCRIPTIONS (continued)
Pin # Signal Name
6
Description
22
IOUT
Fiber Optic Interface Mode:
IOUT (pin 21) is the Fiber optic LED driver output while pin IOUT (pin 22) is optionally used to
provide current peaking. IOUT connects to the cathode of an external LED. It drives NRZI
encoded 100BASE-FX or 100BASE-SX symbols during 100Mb/s mode, Manchester encoded
10BASE-FL data or OPTIDL during 10Mb/s mode, and FLNP Bursts during Auto-Negotiation.
When peaking is not used, IOUT should connect to VCC. When peaking is used, an off-chip
resistor from this pin to ground and an off-chip capacitor from this pin to IOUT determine the
peaking current waveform. (Typical values are 1KW and 1nF)
LVPECL / PECL Compatible Interface Mode:
LVPECL or PECL interface positive and complementary outputs. These outputs form a differential
current output pair that drives NRZI encoded 100BASE-SX or 100BASE-FX symbols during
100Mb/s mode, Manchester encoded 10BASE-FL data or OPTIDL during 10Mb/s mode, and
FLNP Bursts during Auto-Negotiation. IOUT and IOUT are loaded with external resistors to VCC
and AC coupled to the inputs of a 1x9 fiber optic PMD module. A resistor network may be
needed to setup the common mode voltage at the input pins of the PMD module.
36
RTOP
Fiber optic LED or LVPECL/PECL driver bias resistor. An external resistor connected between
RTOP and ground sets a constant bias current for the single ended LED driver or differential
LVPECL/PECL driver circuitry. These output currents depend on the operating mode.
The recommended external component values are:
Fiber Optic Interface mode: (1% resistors, +/- 10% currents)
Indicated is the current into pin IOUT during the High-Light state.
2.8KW between RTOP and ground for 50mA.
2KW between RTOP and ground for 70mA.
1.4KW between RTOP and ground for 100mA.
LVPECL Interface mode:
1.4KW, 1 %, between RTOP and ground for 10mA tail current.
62W , 1 %, between IOUT and VCC.
62W 1 %, between IOUT and VCC.
Also AC couple to PMD inputs.
33
FOINP
2 operating modes are available for these pins and are selected with the configuration pin
PECLQU or the configuration bit LVPECLQU (bit 30.7).
32
FOINN
Fiber Optic Interface Mode:
Fiber optic quantizer positive and complementary inputs. FOINP is capacitively coupled to the
output of a fiber optic receiver, while FOINN is capacitively coupled to the VCC of the fiber
optic receiver. Recommended capacitor values: 10nF, 5%. FOINP voltage must be higher
during the “high light” state than during the low-light state.
LVPECL/PECL Compatible Interface Mode:
LVPECL/PECL interface positive and complementary inputs. These inputs form a differential
input pair that receives 100BASE-FX, 100BASE-SX, FLNP Bursts, or 10BASE-FL signal from a
fiber optic PMD. The PMD outputs are AC coupled to these inputs with .1mF capacitors. The
common mode voltage is set internally with resistors of about 500W from each input pin to an
on-chip voltage reference. FOINP voltage must be higher during the “high light” state than
during the low-light state.
30
CQOS
Fiber Optic Interface Mode:
Data quantizer offset cancellation loop capacitor. An external capacitor between this pin and
VCC determines the dominant pole of the offset cancellation feedback look. The recommended
value is .1mF, 10 %.
LVPECL/PECL Compatible Interface Mode:
This pin is not used and should be left unconnected.
Advanced Datasheet
September 2000
ADVANCED
ML6651
PIN DESCRIPTIONS (continued)
Pin # Signal Name
Description
29
SDFO
Fiber Optic Interface Mode:
This pin is not used and should be connected to any potential between VCC and Ground.
LVPECL/PECL Compatible Interface Mode:
This input pin is connected to the Signal Detect (SD) output of a fiber optic PMD. The voltage
level at this pin is compared to the voltage level at pin SDTH to determine the logic value.
39
SDTH
The voltage at this pin is a single ended LVPECL/PECL reference. Refer to description of SDFO
and REQSD pins.
This pin is not used if either the TPINP/TPINN interface, or the FOINP/FOINN are setup for
LVPECL/PECL compatible mode. In such a case, the SDTH pin must be connected to any
potential between VCC and Ground.
41
TPINSPD
This output pulls up to indicate that 100Mb/s signal is present at the TPINP/TPINN interface, and
it pulls down to indicates that 10Mb/s signal is present at the TPINP/TPINN interface. The signal
can be idle or packets. This pin is set to high impedance otherwise. This pin can also be
configured as a test output (see Test Outputs).
42
FOINSPD
This output pulls up to indicate that 100Mb/s signal is present at the FOINP/FOINN interface,
and it pulls down to indicates that 10Mb/s signal is present at the FOINP/FOINN interface. The
signal can be idle or packets. This pin is set to high impedance otherwise. This pin can also be
configured as a test output (see Test Outputs).
43
TPANDT
When TPINSPD is in the high impedance state, no 10 or 100Mbs signal at TPINP/TPINN, the
TPANDT LED pulls low while receiving Auto-Negotiation signal at the TPINP/TPINN interface.
When TPINSPD is not in the high impedance state, the TPANDTpin pulls low to indicate that a
data packet is being detected at the TPINP/TPINN interface. When a data packet is indicated,
the pulse width at TPANDT is stretch to a minimum of 1.3 to 2.7ms to improve visibility (or
163ms to 328ms, when the TestFast bit 28.0 is 1).
This pin can also be configured as a test output (see Test Outputs).
In any other case this pin is in high impedance state.
44
FOANDT
When FOINSPD is in the high impedance state, no 10 or 100 Mb/s signal at FOINP/FOINN, the
FOANDT LED pulls low while receiving Auto-Negotiation signal at the FOINP/FOINN
interface.
When FOINSPD is not in the high impedance state, the FOANDT pin pulls low to indicate that
a data packet is being detected at the FOINP/FOINN interface. When a data packet is
indicated, the pulse width at FOANDT is stretch to a minimum of 1.3 to 2.7ms to improve
visibility (or 163ms to 328ms, when the TestFast bit 28.0 is 1).
This pin can also be configured as a test output (see Test Outputs).
In any other case this pin is in high impedance state.
40
BCKPLINK
When the Backup Link function is enabled, this pin is the enabler of a secondary link. Connect
to VCC to disable this function. Pull down to ground to enable this function. Recommended pull
down resistor value: 10KW.
7
PECLTP
This pin sets the Media Converter to interface at pins TPINP/TPINN and TPOUTP/TPOUTN, to an
external PECL or LVPECL PMD, or to twisted pair interface magnetics. When PECL or LVPECL
interface is selected, the 100Mb/s scrambler and descrambler functions are disabled by default
and can be enabled with a management register bit. When twisted pair interface is selected,
the scrambler and descrambler are enabled by default and can be disabled with a management
register bit.
When using twisted pair interface, this pin also indicates the maximum supported link distance.
When the 10m maximum link length is selected, the input is not equalized before being sliced.
September 2000
Advanced Datasheet
7
ADVANCED
ML6651
PIN DESCRIPTIONS (continued)
Pin # Signal Name
8
Description
8
PECLQU
This pin sets the Media Converter to interface at pins FOINP/FOINN and IOUT /IOUT, to an
external PECL or LVPECL PMD, or to an LED and a fiber optic receiver.
When using an LED and fiber optic receiver, this pin also indicates the maximum supported link
distance. When the 300m maximum link length is selected, the voltage thresholds for Signal
Detect are increased.
4
AD4LIW
Determines the value of the PHY address bit 4 for accessing the Serial Management Interface,
and determines if the Link Integrity Warning (LIW) function is enabled or disabled.
The Link Integrity Warning (LIW) function can only be enabled when only one SPEED is
available through setting of pin SPEED and/or management registers. When LIW is enabled and
the input link is down at one interface to the Media Converter, the transmitter output on that
interface is turned off for about 425ms every 3.8 seconds (or 104ms every 934ms, when the
TestFast bit 28.0 is 1). It applies to both network interfaces and both data rates. Notice that if the
link at the other interface to the Media Converter is also down, there is never an output. The
LIW function causes the Link Up indicator of the link partner to blink.
5
AD32
Determines the value of the PHY address bits 3 and 2 for accessing the Serial Management
Interface.
6
AD10
Determines the value of the PHY address bits 1 and 0 for accessing the Serial Management
Interface.
25
DUPLEX
This DUPLEX input can have one of three (3) levels. VCC, VCC/2 and 0Volt.
DUPLEX input has 80KW resistors to VCC and Ground. With the input floating the input voltage
is VCC/2. Left open the Transparent mode of operation is enabled.
VCC or 0Volt at the DUPLEX input enables the Non-Transparent mode of operation
27
SPEED
This SPEED input can have one of three (3) levels: VCC, VCC/2, and 0Volt.
VCC input enables only 100Mb/s operation. 10Mb/s and Auto-Negotiation are disabled.
Duplex operation is also disabled.
SPEED input has 80KW resistor to VCC and Ground. With the input floating the input voltage is
VCC/2. Left open, this mode enables 100Mb/s and 10Mb/s operation. The Duplex mode
enables Transparent or Non-Transparent mode operation. Link Integrity Warning (LIW) can be
enabled.
0Volt input on SPEED enables only 10Mb/s operation. 100Mb/s and Auto-Negotiation are
disabled. Duplex operation is also disabled
13
TPOUTOFF
When this input is low, the output stage of the twisted pair output is turned off. CMOS input.
14
FOOUTOFF
When this input is low, the output stage of the fiber optic output is turned off. CMOS input.
24
PWRDWN
When this input is low, all the circuits are powered down. Configuration pins are read and
register bits are initialized, 3 to 8ms after a rising edge of PWRDWN. CMOS input.
18
REFCLOCK
25MHz Reference clock CMOS input. This clock is used for internal digital logic, and as a
reference for the PLLs.
2
GNDT
Ground for the twisted pair driver output stage.
12
GNDE
Ground for the equalizer, one PLL and part of the descrambler and twisted pair driver.
15
GNDD
Ground for CMOS noisy circuits.
20
GNDL
Ground for the fiber optic LED driver output stage.
Advanced Datasheet
September 2000
ADVANCED
ML6651
PIN DESCRIPTIONS (continued)
Pin # Signal Name
Description
28
GNDFC
Ground for one PLL, part of the scrambler, fiber optic LED driver, and quantizer.
34
GNDQ
Ground for the data quantizer and central bias.
35
GNDB
Ground for part of the central biasing.
9
VCCE
Power supply for the equalizer, one PLL and part of the descrambler and twisted pair driver.
19
VCCD
Power supply for CMOS noisy circuits.
23
VCCL
Power supply for the fiber optic LED driver output stage.
26
VCCFC
Power supply for one PLL, part of the scrambler, fiber optic LED driver, and quantizer.
31
VCCQ
Power supply for the data quantizer and central bias.
16
MDIO
Management data TTL input/output pin.
17
MDC
Management clock TTL input. The maximum frequency can be 12.5MHz instead of the 2.5MHz
limit of IEEE 802.3.
September 2000
Advanced Datasheet
9
ADVANCED
ML6651
PHYSICAL DIMENSIONS (inches/millimeters)
Package: H44-10
44-Pin (10 x 10 x 1mm) TQFP
0.472 BSC
(12.00 BSC)
0º - 8º
0.394 BSC
(10.00 BSC)
0.003 - 0.008
(0.09 - 0.20)
34
1
PIN 1 ID
0.394 BSC
(10.00 BSC)
0.472 BSC
(12.00 BSC)
0.018 - 0.030
(0.45 - 0.75)
23
12
0.032 BSC
(0.80 BSC)
0.012 - 0.018
(0.29 - 0.45)
0.048 MAX
(1.20 MAX)
SEATING PLANE
0.037 - 0.041
(0.95 - 1.05)
ORDERING INFORMATION
PART NUMBER
TEMPERATURE RANGE
PACKAGE
ML6651CH
00C to 700C
44 Pin TQFP (10 x 10 x 1.4mm body)
Micro Linear Corporation
2092 Concourse Drive
San Jose, CA 95131
Tel: (408) 433-5200
Fax: (408) 432-0295
www.microlinear.com
DS6651A
10
Advanced Datasheet
September 2000