TI1 DS100MB203SQ 10.3125 gbps dual lane 2:1/1:2 mux/buffer with equalization and de-emphasis Datasheet

DS100MB203
10.3125 Gbps Dual Lane 2:1/1:2 Mux/Buffer with
Equalization and De-Emphasis
General Description
The DS100MB203 is a dual port 2:1 multiplexer and 1:2
switch or fan-out buffer with signal conditioning suitable for
10GE, 10G-KR (802.3ap), Fibre Channel, PCIe, Infiniband,
SATA/SAS and other high speed bus applications with data
rates up to 10.3125 Gbps. The receiver's 4-stage advanced
continuous time linear equalizer (CTLE) provides necessary
boost to compensate up to 40” FR-4 or 20m cable (AWG-24)
at 10.3125 Gbps - This on-chip feature eliminates the need
for external signal conditioners. The transmitter features a
programmable amplitude voltage levels to be selectable from
600 mVp-p to 1300 mVp-p and De-Emphasis of up to 12 dB.
The DS100MB203 can be configured to support PCIe, SAS/
SATA, 10G-KR or other signaling protocols. Based on the
selected operating mode, the DS100MB203 seamlessly
adapts the signal conditioning levels and management of
control signals (SAS/SATA OOB, PCIe BEACONs & IDLE).
While in 10G-KR (802.3ap) or PCIe (Gen-3 only) mode the
DS100MB203 transparently allows the host controller and the
end point to optimize the full link by adjusting transmit equalizer coefficients using back channel signaling. These features
guarantee interoperability at both the electrical and system
level, while reducing design complexity.
With a low power consumption of 390 mW total (typ) and option to turn-off unused channels, the DS100MB203 enables
energy efficient system design. A single supply of 3.3v or 2.5v
is required to power the device. The programmable settings
can be applied via pin settings, SMBus (I2C) protocol or load-
ed directly from an external EEPROM. When operating in the
EEPROM mode, the configuration information is automatically loaded on power up, which eliminates the need for an
external microprocessor or software driver.
Features
■ 10.3125 Gbps Dual Lane 2:1 Mux, 1:2 Switch or Fanout
■ Low 390 mW total power (typ) power consumption, with
■
■
■
■
■
option to power down unused channels
Advanced signal conditioning features
- Receive Equalization up to 36 dB at 5 GHz
- Transmit de-emphasis up to -12 dB
- Transmit output voltage control: 600 mV to 1300 mV
Programmable via pin selection, EEPROM or SMBus
interface
Single supply operation selectable: 2.5V or 3.3V
-40° to +85°C operating temperature range
3 kV HBM ESD rating
Supported Protocols
■
■
■
■
■
■
10GE, 10G-KR
PCIe Gen-1/2/3
SAS/SATA, Fibre Channel
XAUI, RXAUI
sRIO, Infiniband
Other proprietary up to 10.3125 Gbps
Typical Application
30162880
© 2012 Texas Instruments Incorporated
301628 SNLS396A
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DS100MB203 10.3125 Gbps Dual Lane 2:1/1:2 Mux/Buffer with Equalization and De-Emphasis
June 25, 2012
DS100MB203
Pin Diagram
30162892
DS100MB203 Pin Diagram 54 Lead
Ordering Information
NSID
Qty
Spec
Package
DS100MB203SQ
Tape & Reel Supplied As 2,000 Units
NOPB
SQA54A
DS100MB203SQE
Tape & Reel Supplied As 250 Units
NOPB
SQA54A
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2
Pin Name
Pin Number
I/O, Type
Pin Description
Differential High Speed I/O's
D_IN0+, D_IN0-,
D_IN1+, D_IN1-
10, 11,
15, 16
I
Inverting and non-inverting CML differential inputs to the
equalizer. A gated on-chip 50Ω termination resistor connects
D_INn+ to VDD and D_INn- to VDD when enabled.
D_OUT0+, D_ OUT0-,
D_OUT1+, D_OUT1-
3, 4,
7, 8
O
Inverting and non-inverting low power differential signaling
50Ω outputs with de-emphasis. Fully compatible with AC
coupled CML inputs.
S_INA0+, S_INA0-,
S_INA1+, S_INA1-
45, 44,
40, 39
I
Inverting and non-inverting CML differential inputs to the
equalizer. An on-chip 50Ω termination resistor connects
S_INAn+ to VDD and S_INAn- to VDD
S_OUTA0+, S_OUTA0-, 35, 34,
S_OUTA1+, S_OUTA1- 31, 30
O
Inverting and non-inverting low power differential signaling
50Ω outputs with de-emphasis. Fully compatible with AC
coupled CML inputs.
S_INB0+, S_INB0-,
S_INB1+, S_INB1-
I
Inverting and non-inverting CML differential inputs to the
equalizer. An on-chip 50Ω termination resistor connects
S_INBn+ to VDD and S_INBn- to VDD
O
Inverting and non-inverting low power differential signaling
50Ω outputs with de-emphasis. Fully compatible with AC
coupled CML inputs.
I, FLOAT,
LVCMOS
System Management Bus (SMBus) enable pin
43, 42,
38, 37
S_OUTB0+, S_OUTB0-, 33, 32,
S_OUTB1+, S_OUTB1- 29, 28
Control Pins - Shared (LVCMOS)
ENSMB
48
LOW = Pin Mode
FLOAT = Read External EEPROM
HIGH = Register Access SMBus Slave mode
ENSMB = 1 (SMBUS SLAVE MODE), Float (SMBUS MASTER MODE)
SCL
50
I,
LVCMOS,
O, OPEN
Drain
ENSMB Master or Slave mode
SMBUS clock input pin is enabled (slave mode)
SMBUS clock output when loading configuration from
EEPROM (master mode)
SDA
49
I,
LVCMOS,
O, OPEN
Drain
ENSMB Master or Slave mode
The SMBus bi-directional SDA pin is enabled. Data input or
open drain (pull-down only) output.
AD0-AD3
54, 53, 47, 46 I, LVCMOS ENSMB Master or Slave mode
SMBus Slave Address Inputs. In SMBus mode, these pins are
the user set SMBus slave address inputs.
READ_EN
26
I, LVCMOS ENSMB = FLOAT (SMBUS master mode)
When using an External EEPROM, a transition from high to
low starts the load from the external EEPROM
20, 19
46, 47
I, 4-LEVEL, EQ_D[1:0] and EQ_S[1:0] control the level of equalization on
LVCMOS
the high speed input pins. The pins are active only when
ENSMB is deasserted (low). The input are organized into two
sides. The D side is controlled with the EQ_D[1:0] pins and
the S side is controlled with the EQ_S[1:0] pins. When
ENSMB goes high the SMBus registers provide independent
control of each channel. The EQ_S[1:0] pins are converted to
SMBUS AD2/ AD3 inputs. EQ_D[1:0] pins are not used.
ENSMB = 0 (PIN MODE)
EQ_D0, EQ_D1
EQ_S0, EQ_S1
3
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DS100MB203
Pin Descriptions
DS100MB203
Pin Name
Pin Number
I/O, Type
Pin Description
DEM_S0, DEM_S1
DEM_D0, DEM_D1
49, 50
53, 54
I, 4-LEVEL, DEM_D[1:0] and DEM_S[1:0] control the level of VOD and
LVCMOS
de-emphasis on the high speed output. The pins are active
only when ENSMB is deasserted (low). The output are
organized into two sides. The D side is controlled with the
DEM_D[1:0] pins and the S side is controlled with the DEM_S
[1:0] pins. When ENSMB goes high the SMBus registers
provide independent control of each channel. The DEM_D
[1:0] and DEM_S[1:0] pins are converted to SMBUS AD1/AD0
and SCL/SDA inputs.
Control Pins — Both Pin and SMBus Modes (LVCMOS)
MODE
21
I, 4-LEVEL, 0: SATA/SAS, PCIe GEN 1/2 and 10GE
LVCMOS
20kΩ to GND: PCIe GEN 3
FLOAT: AUTO (PCIe GEN 1/2 or GEN 3)
1: 10-KR
INPUT_EN
22
I, 4-LEVEL, 0: Normal Operation, FANOUT is disabled, use SEL0/1 to
LVCMOS
select the A or B input/output (see SEL0/1 pin), input always
enabled with 50 ohms.
20kΩ to GND: Reserved
FLOAT: AUTO - Use RX Detect, SEL0/1 to determine which
input or output to enable, FANOUT is disable
1: Normal Operation, FANOUT is enabled (both S_OUT0/1
are ON). Input always enabled with 50 ohms.
SEL0
23
I, 4-LEVEL, Select pin for Lane 0.
LVCMOS
0: selects input S_INB0+/-, output S_OUTB0+/-.
20kΩ to GND: selects input S_INB0+/-, output S_OUTA0+/-.
FLOAT: selects input S_INA0+/-, output S_OUTB0+/-.
1: selects input S_INA0+/-, output S_OUTA0+/-.
SEL1
26
I, 4-LEVEL, Select pin for Lane 1.
LVCMOS
0: selects input S_INB1+/-, output S_OUTB1+/-.
20kΩ to GND: selects input S_INB1+/-, output S_OUTA1+/-.
FLOAT: selects input S_INA1+/-, output S_OUTB1+/-.
1: selects input S_INA1+/-, output S_OUTA1+/-.
VDD_SEL
25
I, FLOAT
RESET
52
I, LVCMOS 0: Normal Operation (device is enabled).
1: Low Power Mode.
27
0,
LVCMOS
Valid Register Load Status Output
0: External EEPROM load passed
1: External EEPROM load failed
VIN
24
Power
In 3.3V mode, feed 3.3V +/-10% to VIN
In 2.5V mode, leave floating.
VDD
9, 14,36, 41,
51
Power
Power supply pins CML/analog
2.5V mode, connect to 2.5V +/-5%
3.3V mode, connect 0.1 uF cap to each VDD pin
Controls the internal regulator
FLOAT = 2.5V mode
Tied to GND: 3.3V mode
Output (LVCMOS)
ALL_DONE
Power
GND
DAP
Power
Ground pad (DAP - die attach pad).
Notes:
LVCMOS inputs without the “Float” conditions must be driven to a logic low or high at all times or operation is not
guaranteed. Input edge rate for LVCMOS/FLOAT inputs must be faster than 50 ns from 10–90%.
Input edge rate for LVCMOS/FLOAT inputs must be faster than 50 ns from 10–90%.
For 3.3V mode operation, VIN pin = 3.3V and the "VDD" for the 4-level input is 3.3V.
For 2.5V mode operation, VDD pin = 2.5V and the "VDD" for the 4-level input is 2.5V.
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4
If Military/Aerospace specified devices are required,
please contact the Texas Instruments Sales Office/
Distributors for availability and specifications.
Supply Voltage (VDD - 2.5V mode)
Supply Voltage (VIN - 3.3V mode)
LVCMOS Input/Output Voltage
CML Input Voltage
CML Input Current
Junction Temperature
Storage Temperature
SQA54A Package
Derate SQA54A Package
Symbol
-0.5V to +2.75V
-0.5V to +4.0V
-0.5V to +4.0V
-0.5V to (VDD+0.5)
-30 to +30 mA
125°C
-40°C to +125°C
Parameter
Conditions
Power Dissipation
θJC
11.5°C/W
θJA, No Airflow, 4 layer JEDEC
Soldering Information (Note 4)
19.1°C/W
Supply Voltage (2.5V mode)
Supply Voltgae (3.3V mode)
Ambient Temperature
SMBus (SDA, SCL)
Supply Noise up to 50 MHz
(Note 5)
52.6mW/°C above
+25°C
3 kV
200 V
1 kV
Min
Min
2.375
3.0
-40
Typ
2.5
3.3
25
Max
2.625
3.6
+85
3.6
100
Units
V
V
°C
V
mVp-p
Typ
Max
Units
VDD = 2.5 V supply
EQ Enabled,
VOD = 1.0 Vp-p,
RESET = 0
390
499
mW
VIN = 3.3 V supply
EQ Enabled,
VOD = 1.0 Vp-p,
RESET = 0
515
684
mW
2.0
VDD
V
0
0.8
V
Power
PD
LVCMOS / LVTTL DC Specifications
Vih
High Level Input
Voltage
Vil
Low Level Input Voltage
Voh
High Level Output
Voltage
(ALL_DONE pin)
Ioh= −4mA
Vol
Low Level Output
Voltage
(ALL_DONE pin)
Iol= 4mA
Iih
Input High Current
(RESET pin)
VIN = 3.6 V,
LVCMOS = 3.6 V
2.0
Input High Current
with internal resistors
(4–level input pin)
Iil
Input Low Current
(RESET pin)
VIN = 3.6 V,
LVCMOS = 0 V
Input Low Current
with internal resistors
(4–level input pin)
5
V
0.4
V
-15
+15
uA
+20
+150
uA
-15
+15
uA
-160
-40
uA
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DS100MB203
ESD Rating
HBM, STD - JESD22-A114F
MM, STD - JESD22-A115-A
CDM, STD - JESD22-C101-D
Thermal Resistance
Absolute Maximum Ratings (Note 1)
DS100MB203
Symbol
Parameter
Conditions
Min
Typ
Max
Units
CML Receiver Inputs (IN_n+, IN_n-)
RLrx-diff
RLrx-cm
RX Differential return
loss
RX Common mode
return loss
0.05 - 1.25 GHz
-16
dB
1.25 - 2.5 GHz
-16
dB
2.5 - 4.0 GHz
-14
dB
0.05 - 2.5 GHz
-12
dB
2.5 - 4.0 GHz
-8
dB
Zrx-dc
RX DC common mode Tested at VDD = 2.5 V
impedance
40
50
60
Ω
Zrx-diff-dc
RX DC differntial mode Tested at VDD = 2.5 V
impedance
80
100
120
Ω
Vrx-signal-detdiff-pp
Signal detect assert
level for active data
signal
0101 pattern at 10.3125 Gbps
180
mVp-p
Vrx-idle-detdiff-pp
Signal detect de-assert 0101 pattern at 10.3125 Gbps
level for electrical idle
110
mVp-p
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6
Parameter
Conditions
Min
Typ
Max
Units
0.8
1.0
1.2
Vp-p
High Speed Outputs
Vtx-diff-pp
Output Voltage
Differential Swing
Differential measurement
with OUT_n+ and OUT_n-,
terminated by 50Ω to GND,
AC-Coupled, VID = 1.0 Vp-p,
DEM_x[1:0] = R, F,
(Note 8)
Vtx-de-ratio_3.5
TX de-emphasis ratio
VOD = 1.0 Vp-p,
DEM_x[1:0] = R, F
-3.5
dB
Vtx-de-ratio_6
TX de-emphasis ratio
VOD = 1.0 Vp-p,
DEM_x[1:0] = F, 0
-6
dB
TTX-HF-DJ-DD
TX Dj > 1.5 MHz
TTX-HF-DJ-DD
TX RMS jitter < 1.5 MHz
TTX-RISE-FALL
TX rise/fall time
20% to 80% of differential
output voltage
TRF-MISMATCH
TX rise/fall mismatch
20% to 80% of differential
output voltage
0.01
RLTX-DIFF
TX Differential return
loss
0.05 - 1.25 GHz
-16
dB
1.25 - 2.5 GHz
-12
dB
2.5 - 4 GHz
-11
dB
0.05 - 2.5 GHz
-12
dB
-8
dB
100
Ω
35
0.15
UI
3.0
ps RMS
45
ps
0.1
UI
RLTX-CM
TX Common mode
return loss
ZTX-DIFF-DC
DC differential TX
impedance
VTX-CM-AC-PP
TX AC common mode
voltage
ITX-SHORT
TX short circuit current Total current the transmitter
limit
can supply when shorted to
VDD or GND
VTX-CM-DC-
Absolute delta of DC
common mode voltage
during L0 and electrical
idle
100
mV
Absolute delta of DC
common mode voltgae
between TX+ and TX-
25
mV
ACTIVE-IDLE-DELTA
VTX-CM-DC-LINEDELTA
2.5 - 4 GHz
VOD = 1.0 Vp-p,
DEM_x[1:0] = R, F
100
20
mVpp
mA
TTX-IDLE-DATA
Max time to transition to VID = 1.0 Vp-p, 8 Gbps
differential DATA signal
after IDLE
3.5
ns
TTX-DATA-IDLE
Max time to transition to VID = 1.0 Vp-p, 8 Gbps
IDLE after differential
DATA signal
6.2
ns
TPLHD/PHLD
High to Low
EQ = 00, (Note 7)
and Low to High
Differential Propagation
Delay
200
ps
TLSK
Lane to lane skew
T = 25C, VDD = 2.5V
25
ps
TPPSK
Part to part propagation T = 25C, VDD = 2.5V
delay skew
40
ps
TMUX-SWITCH
Mux/Switch Time
100
ns
7
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DS100MB203
Symbol
DS100MB203
Symbol
Parameter
Conditions
Min
Typ
Max
Units
Equalization
DJE1
Residual deterministic 35” 4mils FR4,
jitter at 10.3125 Gbps VID = 0.8 Vp-p,
PRBS15, EQ = 1F'h,
DEM = 0 dB
0.3
UI
DJE2
Residual deterministic 35” 4mils FR4,
jitter at 8 Gbps
VID = 0.8 Vp-p,
PRBS15, EQ = 1F'h,
DEM = 0 dB
0.14
UI
DJE3
Residual deterministic 35” 4mils FR4,
jitter at 5 Gbps
VID = 0.8 Vp-p,
PRBS15,EQ = 1F'h,
DEM = 0 dB
0.1
UI
DJE4
Residual deterministic 35” 4mils FR4,
jitter at 2.5 Gbps
VID = 0.8 Vp-p,
PRBS15, EQ = 1F'h,
DEM = 0 dB
0.05
UI
DJE5
Residual deterministic 10 meters 30 awg cable,
jitter at 10.3125 Gbps VID = 0.8 Vp-p,
PRBS15, EQ = 2F'h,
DEM = 0 dB
0.3
UI
DJE6
Residual deterministic 10 meters 30 awg cable,
jitter at 8 Gbps
VID = 0.8 Vp-p,
PRBS15, EQ = 2F'h,
DEM = 0 dB
0.16
UI
DJE7
Residual deterministic 10 meters 30 awg cable,
jitter at 5 Gbps
VID = 0.8 Vp-p,
PRBS15, EQ = 2F'h,
DEM = 0 dB
0.1
UI
DJE8
Residual deterministic 10 meters 30 awg cable,
jitter at 2.5 Gbps
VID = 0.8 Vp-p,
PRBS15, EQ = 2F'h,
DEM = 0 dB
0.05
UI
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8
Parameter
Conditions
Min
Typ
Max
Units
De-emphasis (MODE = 0)
DJD1
Residual deterministic 10” 4mils FR4,
jitter at 2.5 Gbps and VID = 0.8 Vp-p,
5.0 Gbps
PRBS15, EQ = 00,
VOD = 1.0 Vp-p,
DEM = −3.5 dB
0.1
UI
DJD2
Residual deterministic 20” 4mils FR4,
jitter at 2.5 Gbps and VID = 0.8 Vp-p,
5.0 Gbps
PRBS15, EQ = 00,
VOD = 1.0 Vp-p,
DEM = −9 dB
0.1
UI
DJD3
Residual deterministic 20” 4mils FR4,
jitter at 10.3125 Gbps VID = 0.8 Vp-p,
PRBS15, EQ = 00,
VOD = 1.0 Vp-p,
DEM = −9 dB
0.1
UI
Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur, including inoperability and degradation of device reliability
and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or other conditions beyond those indicated in
the Recommended Operating Conditions is not implied. The Recommended Operating Conditions indicate conditions at which the device is functional and the
device should not be operated beyond such conditions. Absolute Maximum Numbers are guaranteed for a junction temperature range of -40°C to +125°C. Models
are validated to Maximum Operating Voltages only.
Note 2: Typical values represent most likely parametric norms at VDD = 2.5V, TA = 25°C., and at the Recommended Operation Conditions at the time of product
characterization and are not guaranteed.
Note 3: The Electrical Characteristics tables list guaranteed specifications under the listed Recommended Operating Conditions except as otherwise modified
or specified by the Electrical Characteristics Conditions and/or Notes. Typical specifications are estimations only and are not guaranteed.
Note 4: See Application Note SNOA549C: http://www.ti.com/lit/an/snoa549c/snoa549c.pdf
Note 5: Allowed supply noise (mVp-p sine wave) under typical conditions.
Note 6: Guaranteed by device characterization.
Note 7: Propagation Delay measurements will change slightly based on the level of EQ selected. EQ = 00 will result in the shortest propagation delays.
Note 8: In GEN3 mode, the output VOD level is not fixed. It will be adjusted automatically based on the VID input amplitude level. The output VOD level set by
DEM_x[1:0] in GEN3 mode is dependent on the VID level and the frequency content. The DS100MB203 repeater in GEN3 mode is designed to be transparent,
so the TX-FIR (de-emphasis) is passed to the RX to support the PCIe GEN3 handshake negotiation link training.
9
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DS100MB203
Symbol
DS100MB203
Electrical Characteristics — Serial Management Bus Interface
Over recommended operating supply and temperature ranges unless other specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
0.8
V
3.6
V
SERIAL BUS INTERFACE DC SPECIFICATIONS
VIL
Data, Clock Input Low Voltage
VIH
Data, Clock Input High Voltage
IPULLUP
Current Through Pull-Up Resistor High Power Specification
or Current Source
VDD
Nominal Bus Voltage
ILEAK-Bus
Input Leakage Per Bus Segment
ILEAK-Pin
Input Leakage Per Device Pin
CI
Capacitance for SDA and SCL
RTERM
External Termination Resistance Pullup VDD = 3.3V,
pull to VDD = 2.5V ± 5% OR 3.3V ± (Note 9, Note 10, Note 11)
10%
Pullup VDD = 2.5V,
(Note 9, Note 10, Note 11)
2.1
(Note 9)
4
mA
2.375
3.6
V
-200
+200
µA
-15
(Note 9, Note 10)
µA
10
pF
2000
Ω
1000
Ω
SERIAL BUS INTERFACE TIMING SPECIFICATIONS
FSMB
Bus Operating Frequency
ENSMB = VDD (Slave Mode)
ENSMB = FLOAT (Master Mode)
280
400
400
kHz
520
kHz
TBUF
Bus Free Time Between Stop and
Start Condition
1.3
µs
THD:STA
Hold time after (Repeated) Start
At IPULLUP, Max
Condition. After this period, the first
clock is generated.
0.6
µs
TSU:STA
Repeated Start Condition Setup
Time
0.6
µs
TSU:STO
Stop Condition Setup Time
0.6
µs
THD:DAT
Data Hold Time
0
ns
TSU:DAT
Data Setup Time
100
ns
TLOW
Clock Low Period
THIGH
Clock High Period
(Note 12)
tF
Clock/Data Fall Time
tR
Clock/Data Rise Time
tPOR
Time in which a device must be
operational after power-on reset
(Note 12, Note 13)
1.3
0.6
µs
50
µs
(Note 12)
300
ns
(Note 12)
300
ns
500
ms
Note 9: Recommended value.
Note 10: Recommended maximum capacitance load per bus segment is 400pF.
Note 11: Maximum termination voltage should be identical to the device supply voltage.
Note 12: Compliant to SMBus 2.0 physical layer specification. See System Management Bus (SMBus) Specification Version 2.0, section 3.1.1 SMBus common
AC specifications for details.
Note 13: Guaranteed by Design. Parameter not tested in production.
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10
DS100MB203
Timing Diagrams
30162802
FIGURE 1. CML Output and Rise and FALL Transition Time
30162803
FIGURE 2. Propagation Delay Timing Diagram
30162804
FIGURE 3. Transmit IDLE-DATA and DATA-IDLE Response Time
30162805
FIGURE 4. SMBus Timing Parameters
11
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DS100MB203
The input control pins have been enhanced to have 4 different
levels and provide a wider range of control settings when ENSMB=0.
Functional Descriptions
The DS100MB203is a dual lane 2:1 multiplexer and 1:2
switch or fan-out buffer with signal conditioning. The
DS100MB203 compensates for lossy FR-4 printed circuit
board backplanes and balanced cables. The DS100MB203
operates in 3 modes: Pin Control Mode (ENSMB = 0), SMBus
Slave Mode (ENSMB = 1) and SMBus Master Mode (ENSMB
= float) to load register informations from external EEPROM;
please refer to SMBUS Master Mode for additional information.
Pin Control Mode:
When in pin mode (ENSMB = 0), equalization and de-emphasis can be selected via pin for each side independently.
When de-emphasis is asserted VOD is automatically adjusted per the De-Emphasis table below.
SMBUS Mode:
When in SMBus mode (ENSMB = 1), the VOD (output amplitude), equalization, de-emphasis, and termination disable
features are all programmable on a individual lane basis, instead of grouped by D or S as in the pin mode case. Upon
assertion of ENSMB, the EQx and DEMx functions revert to
register control immediately. The EQx and DEMx pins are
converted to AD0-AD3 SMBus address inputs. On power-up
and when ENSMB is driven low all registers are reset to their
default state. If RESET is asserted (tied High) while ENSMB
is high, the registers retain their current state.
Equalization settings accessible via the pin controls were
chosen to meet the needs of most PCIe applications. If additional fine tuning or adjustment is needed, additional equalization settings can be accessed via the SMBus registers.
Each input has a total of 256 possible equalization settings.
The tables show the 16 setting when the device is in pin mode.
When using SMBus mode, the equalization, VOD and deEmphasis levels are set by registers.
Table 1: 4–Level Control Pin
Settings
Pin Setting
Description
Voltage at Pin
0
Tie 1kΩ to GND
0.03 x VDD
R
Tie 20kΩ to GND
1/3 x VDD
Float
Float (leave pin open) 2/3 x VDD
1
Tie 1kΩ to VDD
0.98 x VDD
Note: The above required resistor value is for a single
device. When there are multiple devices connected to the
pull-up / pull-down resistor, the value must scale with the
number of devices. If 4 devices are connected to a single
pull-up or pull-down, the 1kΩ resistor value should be
250Ω. For the 20kΩ to GND, this should also scale to 5kΩ.
3.3V or 2.5V Supply Mode Operation
The DS100MB203 has an optional internal voltage regulator
to provide the 2.5V supply to the device. In 3.3V mode, the
VIN pin = 3.3V is used to supply power to the device and the
VDD pins should be left open. The internal regulator will provide the 2.5V to the VDD pins of the device and a 0.1 uF cap
is needed at each of 5 VDD pins for power supply de-coupling
(total capacitance should be ≤0.5 uF). The VDD_SEL pin
must be tied to GND to enable the internal regulator. In 2.5V
mode, the VIN pin should be left open and 2.5V supply must
be applied to the VDD pins. The VDD_SEL pin must be left
open (no connect) to disable the internal regulator.
30162806
FIGURE 5. 3.3V or 2.5V Supply Connection Diagram
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12
DS100MB203
Table 2: Equalizer Settings
Level
EQ–D1
EQ_S1
EQ_D0
EQ_S0
EQ – 8 bits [7:0]
dB at
dB at
1.25 GHz 2.5 GHz
dB at
4 GHz
dB at
5 GHz
Suggested Use
1
0
0
0000 0000 = 0x00
2.1
3.7
4.9
5.3
FR4 < 5 inch trace
2
0
R
0000 0001 = 0x01
3
0
Float
0000 0010 = 0x02
3.4
5.8
7.9
8.7
FR4 5 inch 5–mil trace
4.8
7.7
9.9
10.6
4
0
1
FR4 5 inch 4–mil trace
0000 0011 = 0x03
5.9
8.9
11.0
11.7
FR4 10 inch 5–mil trace
5
R
6
R
0
0000 0111 = 0x07
7.2
11.2
14.3
15.6
FR4 10 inch 4–mil trace
R
0001 0101 = 0x15
6.1
11.4
14.6
16.6
7
R
FR4 15 inch 4–mil trace
Float
0000 1011 = 0x0B
8.8
13.5
17.0
18.3
FR4 20 inch 4–mil trace
8
9
R
1
0000 1111 = 0x0F
10.2
15.0
18.5
19.7
FR4 25 to 30 inch 4–mil trace
Float
0
0101 0101 = 0x55
7.5
12.8
18.0
20.3
10
FR4 30 inch 4–mil trace
Float
R
0001 1111 = 0x1F
11.4
17.4
22.0
23.6
FR4 35 inch 4–mil trace
11
Float
Float
0010 1111 = 0x2F
13.0
19.7
24.4
25.8
10m, 30awg cable
12
Float
1
0011 1111 = 0x3F
14.2
21.1
25.8
27.0
10m – 12m cable
13
1
0
1010 1010 = 0xAA
13.8
21.7
27.4
29.1
14
1
R
0111 1111 = 0x7F
15.6
23.5
29.0
30.7
15
1
Float
1011 1111 = 0xBF
17.2
25.8
31.4
32.7
16
1
1
1111 1111 = 0xFF
18.4
27.3
32.7
33.8
Table 3: De-emphasis and Output Voltage Settings
Level
DEM_D1
DEM_S1
DEM_D0
DEM_S0
VOD Vp-p
DEM dB
Inner Amplitude
Vp-p
Suggested Use
1
2
0
0
0.6
0
0.6
FR4 <5 inch 4–mil trace
0
R
0.8
0
0.8
3
FR4 <5 inch 4–mil trace
0
Float
0.8
- 3.5
0.55
FR4 10 inch 4–mil trace
4
0
1
0.9
0
1.0
FR4 <5 inch 4–mil trace
5
R
0
0.9
- 3.5
0.45
FR4 10 inch 4–mil trace
6
R
R
0.9
-6
0.5
FR4 15 inch 4–mil trace
7
R
Float
1.0
0
1.0
FR4 <5 inch 4–mil trace
8
R
1
1.0
- 3.5
0.7
FR4 10 inch 4–mil trace
9
Float
0
1.0
-6
0.5
FR4 15 inch 4–mil trace
10
Float
R
1.1
0
1.1
FR4 <5 inch 4–mil trace
11
Float
Float
1.1
- 3.5
0.7
FR4 10 inch 4–mil trace
12
Float
1
1.1
-6
0.55
FR4 15 inch 4–mil trace
13
1
0
1.2
0
1.2
FR4 <5 inch 4–mil trace
14
1
R
1.2
- 3.5
0.8
FR4 10 inch 4–mil trace
15
1
Float
1.2
-6
0.6
FR4 15 inch 4–mil trace
16
1
1
1.2
-9
0.45
FR4 20 inch 4–mil trace
13
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DS100MB203
Table 4: Input Termination Condition with RESET, INPUT_EN and SEL0 / SEL1
RESET INPUT_EN
SEL0
SEL1
Mode
Input_Term
S_INA0
S_INA1
Input_Term
S_INB0
S_INB1
Input_Term
D_IN0
D_IN1
1
X
X
Low Power
High Z
High Z
High Z
0
0
X
Manual Mux
Mode
50 Ω
50 Ω
50 Ω
0
R
X
Reserved
Reserved
Reserved
Reserved
0
F
0
Auto High Z
continuous poll,
DIN_B
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
0
F
R
Auto High Z
continuous poll,
DIN_B
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
0
F
F
Auto Auto RX-Detect, output High Z
continuous poll, tests every 12msec until
DIN_A
detection occcurs, input
termination is high-z
until detection; once
detected input
termination is 50 Ohm
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
0
F
1
Auto Auto RX-Detect, output High Z
continuous poll, tests every 12msec until
DIN_A
detection occcurs, input
termination is high-z
until detection; once
detected input
termination is 50 Ohm
Auto RX-Detect, output
tests every 12msec until
detection occcurs, input
termination is high-z until
detection; once detected
input termination is 50
Ohm
0
1
X
Manual Fanout 50 Ω
Mode
50 Ω
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50 Ω
14
DS100MB203
Table 5: Mux/Switch and FANOUT Control
SEL0
SEL1
INPUT_EN
0
0
0
Description of Connection Path
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTB0. S_OUTA0 is in IDLE (output muted).
D_IN1 connects to S_OUTB1. S_OUTA1 is in IDLE (output muted).
0
0
R
Reserved
0
0
F
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTB0. S_OUTA0 is in IDLE (output muted).
D_IN1 connects to S_OUTB1. S_OUTA1 is in IDLE (output muted).
0
0
1
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTB0 and S_OUTA0.
D_IN1 connects to S_OUTB1 and S_OUTA1.
R
R
0
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTA0. S_OUTB0 is in IDLE (output muted).
D_IN1 connects to S_OUTA1. S_OUTB1 is in IDLE (output muted).
R
R
R
Reserved
R
R
F
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTA0. S_OUTB0 is in IDLE (output muted).
D_IN1 connects to S_OUTA1. S_OUTB1 is in IDLE (output muted).
R
R
1
D_OUT0 connects to S_INB0.
D_OUT1 connects to S_INB1.
D_IN0 connects to S_OUTB0 and S_OUTA0.
D_IN1 connects to S_OUTB1 and S_OUTA1.
F
F
0
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTB0. S_OUTA0 is in IDLE (output muted).
D_IN1 connects to S_OUTB1. S_OUTA1 is in IDLE (output muted).
F
F
R
Reserved
F
F
F
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTB0. S_OUTA0 is in IDLE (output muted).
D_IN1 connects to S_OUTB1. S_OUTA1 is in IDLE (output muted).
F
F
1
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTB0 and S_OUTA0.
D_IN1 connects to S_OUTB1 and S_OUTA1.
1
1
0
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTA0. S_OUTB0 is in IDLE (output muted).
D_IN1 connects to S_OUTA1. S_OUTB1 is in IDLE (output muted).
1
1
R
Reserved
1
1
F
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTA0. S_OUTB0 is in IDLE (output muted).
D_IN1 connects to S_OUTA1. S_OUTB1 is in IDLE (output muted).
1
1
1
D_OUT0 connects to S_INA0.
D_OUT1 connects to S_INA1.
D_IN0 connects to S_OUTA0 and S_OUTB0.
D_IN1 connects to S_OUTA1 and S_OUTB1.
15
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DS100MB203
SMBUS Master Mode
The DS100MB203 devices support reading directly from an external EEPROM device by implementing SMBus Master mode.
When using the SMBus master mode, the DS100MB203 will read directly from specific location in the external EEPROM. When
designing a system for using the external EEPROM, the user needs to follow these specific guidelines below. NOTE: SEL0, SEL1
and INPUT_EN control are to be set with the external strap pins because there no register bits to configure them.
•
•
•
Set ENSMB = Float — enable the SMBUS master mode.
The external EEPROM device address byte must be 0xA0'h and capable of 400 kHz operation at 2.5V and 3.3V supply.
Set the AD[3:0] inputs for SMBus address byte. When the AD[3:0] = 0000'b, the device address byte is B0'h.
When tying multiple DS100MB203 devices to the SDA and SCL bus, use these guidelines to configure the devices.
•
•
•
Use SMBus AD[3:0] address bits so that each device can loaded it's configuration from the EEPROM. Example below is for 4
device.
U1: AD[3:0] = 0000 = 0xB0'h,
U2: AD[3:0] = 0001 = 0xB2'h,
U3: AD[3:0] = 0010 = 0xB4'h,
U4: AD[3:0] = 0011 = 0xB6'h
Use a pull-up resistor on SDA and SCL; value = 2k ohms
Daisy-chain READEN# (pin 26) and ALL_DONE# (pin 27) from one device to the next device in the sequence so that they do
not compete for the EEPROM at the same time.
1. Tie READEN# of the 1st device in the chain (U1) to GND
2. Tie ALL_DONE# of U1 to READEN# of U2
3. Tie ALL_DONE# of U2 to READEN# of U3
4. Tie ALL_DONE# of U3 to READEN# of U4
5. Optional: Tie ALL_DONE# output of U4 to a LED to show the devices have been loaded successfully
Below is an example of a 2 kbits (256 x 8-bit) EEPROM in hex format for the DS100MB203 device. The first 3 bytes of the EEPROM
always contain a header common and necessary to control initialization of all devices connected to the I2C bus. CRC enable flag
to enable/disable CRC checking. If CRC checking is disabled, a fixed pattern (8’hA5) is written/read instead of the CRC byte from
the CRC location, to simplify the control. There is a MAP bit to flag the presence of an address map that specifies the configuration
data start in the EEPROM. If the MAP bit is not present the configuration data start address is derived from the DS100MB203
address and the configuration data size. A bit to indicate an EEPROM size > 256 bytes is necessary to properly address the
EEPROM. There are 37 bytes of data size for each DS100MB203 device.
:2000000000001000000407002FAD4002FAD4002FAD4002FAD401805F5A8005F5A8005F5AD8
:200020008005F5A800005454000000000000000000000000000000000000000000000000F6
:20006000000000000000000000000000000000000000000000000000000000000000000080
:20008000000000000000000000000000000000000000000000000000000000000000000060
:2000A000000000000000000000000000000000000000000000000000000000000000000040
:2000C000000000000000000000000000000000000000000000000000000000000000000020
:2000E000000000000000000000000000000000000000000000000000000000000000000000
:200040000000000000000000000000000000000000000000000000000000000000000000A0
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16
Byte
0
ch1_RES_1
00
Description 14
Binary
1
ch1_RES_0
Binary
1
Description 13
D4
Binary
ch1_BST_3
Description 12
FA
0
ch1_RES
02
Description 11
Binary
0
ch0_RES_2
Binary
1
Description 10
40
Binary
ch0_RES
Description 9
AD
0
ch0_BST_7
Binary
0
2F
Description 8
RD_delay_sel_3
Description 7
Binary
0
Binary
00
RES
Description 6
07
0
RES
Binary
0
Description 5
04
Binary
RES
Description 4
00
0
PWDN_ch7
Binary
0
Description 3
00
Binary
Max EEPROM
Burst size[7]
Description 2
10
0
RES
00
Binary
Description 1
CRC EN
Bit 7
0
00
HEX
Binary
Description 0
EEPROM
Address
0
Ovrd_MODE
0
RES
0
RES
0
PWDN_ch5
0
Max EEPROM
Burst size[5]
0
RES
0
EEPROM > 256
Bytes
Bit 5
0
ch1_RES_0
1
ch1_VOD_2
1
ch1_BST_2
0
ch1_RES
1
ch0_RES_1
0
ch0_RES
0
ch0_BST_6
0
0
ch1_RES_1
0
ch1_VOD_1
1
ch1_BST_1
0
ch1_RXDET_1
0
ch0_RES_0
1
ch0_RES_2
1
ch0_BST_5
0
RD_delay_sel_2 RD_delay_sel_1
0
Ovrd_RX_DET
0
RES
0
RES
0
PWDN_ch6
0
Max EEPROM
Burst size[6]
0
RES
0
Address Map
Present
Bit 6
Table 6: EEPROM Register Map with Default Value
0
ch1_RES_0
1
ch1_VOD_0
1
ch1_BST_0
0
ch1_RXDET_0
0
ch0_Slow
0
ch0_RES_1
0
ch0_BST_4
0
RD_delay_sel_0
0
RES
0
RES
0
RES
0
PWDN_ch4
1
Max EEPROM
Burst size[4]
0
RES
0
RES
Bit 4
0
ch2_RES
0
ch1_DEM_2
1
ch1_Sel_scp
0
ch1_BST_7
0
ch0_RES_1
1
ch0_RES_0
1
ch0_BST_3
0
RES
0
RES
0
RES
0
Ovrd_RESET
0
PWDN_ch3
0
Max EEPROM
Burst size[3]
0
RES
0
RES
Bit 3
0
ch2_RES
1
ch1_DEM_1
0
ch1_Sel_MODE
0
ch1_BST_6
0
ch0_RES_0
1
ch0_RES_2
1
ch0_BST_2
0
RES
1
rx_delay_sel_2
1
rxdet_btb_en
0
RES
0
PWDN_ch2
0
Max EEPROM
Burst size[2]
0
RES
0
RES
Bit 2
0
ch2_RXDET_1
0
ch1_DEM_0
1
ch1_RES_2
1
ch1_BST_5
0
ch0_RES_1
0
ch0_RES_1
1
ch0_BST_1
0
ch0_RXDET_1
1
rx_delay_sel_1
0
RES
0
RES
0
PWDN_ch1
0
Max EEPROM
Burst size[1]
0
RES
0
RES
Bit 1
0
ch2_RXDET_0
0
ch1_Slow
0
ch1_RES_1
0
ch1_BST_4
0
ch0_RES_0
1
ch0_RES_0
1
ch0_BST_0
0
ch0_RXDET_0
1
rx_delay_sel_0
0
RES
0
RES
0
PWDN_ch0
0
Max EEPROM
Burst size[0]
0
RES
0
RES
BIt 0
DS100MB203
17
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18
Binary
0
ch6_Sel_MODE
Description 31
5A
0
ch6_BST_6
5F
Description 30
Binary
0
ch5_RES_0
Binary
1
Description 29
00
Binary
ch5_VOD_2
Description 28
A8
1
ch5_RES
F5
Description 27
Binary
0
ch5_RES
Binary
1
Description 26
05
Binary
ch4_DEM_1
Description 25
80
0
ch4_Sel_MODE
Binary
0
Description 24
5A
Binary
ch4_BST_6
Description 23
5F
1
en_fast_idle_s
80
Description 22
Binary
0
ch3_RES_1
Binary
1
Description 21
01
Binary
ch3_RES_0
Description 20
D4
1
ch3_BST_3
Binary
0
Description 19
FA
Binary
ch3_RES
Description 18
02
0
ch2_RES_2
40
Description 17
Binary
1
ch2_RES
Binary
0
AD
ch2_BST_7
Description 16
2F
Binary
Description 15
1
ch6_RES_2
1
ch6_BST_5
0
ch5_RES_1
0
ch5_VOD_1
1
ch5_RES
0
ch5_RES
0
ch4_DEM_0
1
ch4_RES_2
1
ch4_BST_5
0
eqsd_mgain_n
0
ch3_RES_0
1
ch3_VOD_2
1
ch3_BST_2
0
ch3_RES
1
ch2_RES_1
0
ch2_RES
0
ch2_BST_6
0
ch6_RES_1
0
ch6_BST_4
0
ch5_RES_0
1
ch5_VOD_0
1
ch5_RES
0
ch5_RES
0
ch4_Slow
0
ch4_RES_1
0
ch4_BST_4
0
eqsd_mgain_s
0
ch3_RES_1
0
ch3_VOD_1
1
ch3_BST_1
0
ch3_RXDET_1
0
ch2_RES_0
1
ch2_RES_2
1
ch2_BST_5
1
ch6_RES_0
1
ch6_BST_3
0
ch6_RES
0
ch5_DEM_2
1
ch5_Sel_scp
0
ch5_RES
0
ch4_RES_1
1
ch4_RES_0
1
ch4_BST_3
0
ch4_RES
0
ch3_RES_0
1
ch3_VOD_0
1
ch3_BST_0
0
ch3_RXDET_0
0
ch2_Slow
0
ch2_RES_1
0
ch2_BST_4
1
ch6_VOD_2
1
ch6_BST_2
0
ch6_RES
1
ch5_DEM_1
0
ch5_Sel_MODE
0
ch5_RES
0
ch4_RES_0
1
ch4_VOD_2
1
ch4_BST_2
0
ch4_RES
0
ovrd_fast_idle
0
ch3_DEM_2
1
ch3_Sel_scp
0
ch3_BST_7
0
ch2_RES_1
1
ch2_RES_0
1
ch2_BST_3
0
ch6_VOD_1
1
ch6_BST_1
0
ch6_RXDET_1
0
ch5_DEM_0
1
ch5_RES_2
1
ch5_RES
0
ch4_RES_1
0
ch4_VOD_1
1
ch4_BST_1
0
ch4_RXDET_1
0
en_h_idle_th_n
1
ch3_DEM_1
0
ch3_Sel_MODE
0
ch3_BST_6
0
ch2_RES_0
1
ch2_RES_2
1
ch2_BST_2
1
ch6_VOD_0
1
ch6_BST_0
0
ch6_RXDET_0
0
ch5_Slow
0
ch5_RES_1
0
ch5_RES
0
ch4_RES_0
1
ch4_VOD_0
1
ch4_BST_0
0
ch4_RXDET_0
0
en_h_idle_th_s
0
ch3_DEM_0
1
ch3_RES_2
1
ch3_BST_5
0
ch2_RES_1
0
ch2_RES_1
1
ch2_BST_1
0
ch6_DEM_2
1
ch6_Sel_scp
0
ch6_BST_7
0
ch5_RES_1
1
ch5_RES_0
1
ch5_RES
0
ch5_RES
0
ch4_DEM_2
1
ch4_Sel_scp
0
ch4_BST_7
1
en_fast_idle_n
0
ch3_Slow
0
ch3_RES_1
0
ch3_BST_4
0
ch2_RES_0
1
ch2_RES_0
1
ch2_BST_0
DS100MB203
0
DEM__ovrd_S2
Binary
0
54
Description 39
DEM_ovrd_N2
Binary
0
54
Description 38
ipp_dac_0
Binary
0
Description 37
00
Binary
ch7_RES_0
Description 36
00
1
ch7_VOD_2
A8
Description 35
Binary
1
ch7_RES
Binary
0
Description 34
F5
Binary
ch7_RES
05
Description 33
ch6_DEM_1
1
80
Binary
Description 32
1
DEM__ovrd_S1
1
DEM_ovrd_N1
0
RD23_67
0
ch7_RES_1
0
ch7_VOD_1
1
ch7_RES
0
ch7_RES
0
ch6_DEM_0
0
DEM_ovrd_S0
0
DEM_ovrd_N0
0
RD01_45
0
ch7_RES_0
1
ch7_VOD_0
1
ch7_RES
0
ch7_RES
0
ch6_Slow
1
VOD_ovrd_S2
1
VOD_ovrd_N2
0
RD_PD_ovrd
0
iph_dac_ns_1
0
ch7_DEM_2
1
ch7_Sel_scp
0
ch7_RES
0
ch6_RES_1
0
VOD_ovrd_S1
0
VOD_ovrd_N1
0
RD_Sel_test
0
iph_dac_ns_0
1
ch7_DEM_1
0
ch7_Sel_MODE
0
ch7_RES
0
ch6_RES_0
1
VOD_ovrd_S0
1
VOD_ovrd_N0
0
RD_RESET_ovrd
0
ipp_dac_ns_1
0
ch7_DEM_0
1
ch7_RES_2
1
ch7_RES
0
ch6_RES_1
0
ipp_dac_1
0
ch7_RES_1
1
ch7_RES_0
1
ch7_RES
0
ch7_RES
0
SPARE0
0
SPARE0
0
0
SPARE1
0
SPARE1
0
PWDB_input_DC DEM_VOD_ovrd
0
ipp_dac_ns_0
0
ch7_Slow
0
ch7_RES_1
0
ch7_RES
0
ch6_RES_0
DS100MB203
19
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DS100MB203
START: A High-to-Low transition on SDA while SCL is High
indicates a message START condition.
STOP: A Low-to-High transition on SDA while SCL is High
indicates a message STOP condition.
IDLE: If SCL and SDA are both High for a time exceeding
tBUF from the last detected STOP condition or if they are High
for a total exceeding the maximum specification for tHIGH then
the bus will transfer to the IDLE state.
System Management Bus (SMBus)
and Configuration Registers
The System Management Bus interface is compatible to SMBus 2.0 physical layer specification. ENSMB = 1kΩ to VDD to
enable SMBus slave mode and allow access to the configuration registers.
The DS100MB203 has the AD[3:0] inputs in SMBus mode.
These pins are the user set SMBUS slave address inputs. The
AD[3:0] pins have internal pull-down. When left floating or
pulled low the AD[3:0] = 0000'b, the device default address
byte is B0'h. Based on the SMBus 2.0 specification, the
DS100MB203 has a 7-bit slave address. The LSB is set to 0'b
(for a WRITE). The device supports up to 16 address byte,
which can be set with the AD[3:0] inputs. Below are the 16
addresses.
SMBus TRANSACTIONS
The device supports WRITE and READ transactions. See
Register Description table for register address, type (Read/
Write, Read Only), default value and function information.
WRITING A REGISTER
To write a register, the following protocol is used (see SMBus
2.0 specification).
1. The Host drives a START condition, the 7-bit SMBus
address, and a “0” indicating a WRITE.
2. The Device (Slave) drives the ACK bit (“0”).
3. The Host drives the 8-bit Register Address.
4. The Device drives an ACK bit (“0”).
5. The Host drive the 8-bit data byte.
6. The Device drives an ACK bit (“0”).
7. The Host drives a STOP condition.
The WRITE transaction is completed, the bus goes IDLE and
communication with other SMBus devices may now occur.
Table 7: Device Slave Address Bytes
AD[3:0] Settings
Address Bytes (HEX)
0000
B0
0001
B2
0010
B4
0011
B6
0100
B8
0101
BA
0110
BC
0111
BE
1000
C0
1001
C2
1010
C4
1011
C6
1100
C8
1101
CA
1110
CC
1111
CE
READING A REGISTER
To read a register, the following protocol is used (see SMBus
2.0 specification).
1. The Host drives a START condition, the 7-bit SMBus
address, and a “0” indicating a WRITE.
2. The Device (Slave) drives the ACK bit (“0”).
3. The Host drives the 8-bit Register Address.
4. The Device drives an ACK bit (“0”).
5. The Host drives a START condition.
6. The Host drives the 7-bit SMBus Address, and a “1”
indicating a READ.
7. The Device drives an ACK bit “0”.
8. The Device drives the 8-bit data value (register contents).
9. The Host drives a NACK bit “1”indicating end of the
READ transfer.
10. The Host drives a STOP condition.
The READ transaction is completed, the bus goes IDLE and
communication with other SMBus devices may now occur.
Please see SMBus Register Map Table for more information.
The SDA, SCL pins are 3.3V tolerant, but are not 5V tolerant.
External pull-up resistor is required on the SDA. The resistor
value can be from 1 kΩ to 5 kΩ depending on the voltage,
loading and speed. The SCL may also require an external
pull-up resistor and it depends on the Host that drives the bus.
TRANSFER OF DATA VIA THE SMBus
During normal operation the data on SDA must be stable during the time when SCL is High.
There are three unique states for the SMBus:
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20
DS100MB203
Table 8: SMBUS Slave Mode Register Map
Address Register Name
Bit (s) Field
Type Defaul Description
t
0x00
7
Reserved
R/W
6:3
Address Bit
AD[3:0]
R
Observation of AD[3:0] bit
[6]: AD3
[5]: AD2
[4]: AD1
[3]: AD0
2
EEPROM Read
Done
R
1: Device completed the read from external
EEPROM.
1
Block Reset
R/W
1: Block bit 0 from resetting the registers; self
clearing.
0
Reset
R/W
SMBus Reset
1: Reset registers to default value; self clearing.
Observation,
SMBus Reset
0x00
Set bit to 0.
0x01
PWDN Channels
7:0
PWDN CHx
R/W
0x00
Power Down per Channel
[7]: CH7 (NC – S_OUTB1)
[6]: CH6 (D_IN1 – S_OUTA1)
[5]: CH5 (NC – S_OUTB0)
[4]: CH4 (D_IN0 – S_OUTA0)
[3]: CH3 (D_OUT1 – S_INB1)
[2]: CH2 (NC – S_INA1)
[1]: CH1 (D_OUT0 – S_INB0)
[0]: CH0 (NC – S_INA0)
00'h = all channels enabled
FF'h = all channels disabled; device in low power
state
Note: override RESET pin in Reg_02.
0x02
Override
RESET Control
7:1
Reserved
R/W
0x00
Set bits to 0.
0
Override RESET
0x05
Slave Mode CRC
Bits
7:0
CRC bits
R/W
0x00
CRC bits [7:0]
0x06
Slave CRC Control 7:5
Reserved
R/W
0x10
Set bits to 0.
0x08
Override RXDET,
MODE
1: Block RESET pin control; use Reg_01 to
configure.
0: Allow RESET pin control.
4
Reserved
Set bit to 1.
3
Slave CRC
1: Disables the slave CRC mode
0: Enables the slave CRC mode
Note: In order to change VOD, DEM and EQ of the
channels in slave mode, set bit to 1 to disable the
CRC.
2:0
Reserved
7:4
Reserved
3
Override RXDET
1: Block RXDET control; use register to configure.
0: Allow RXDET control.
2
Override MODE
1: Block MODE pin control; use register to
configure.
0: Allow MODE pin control
Set bits to 0.
R/W
1:0
0x00
Set bits to 0.
Set bits to 0.
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DS100MB203
0x0E
CH0 - S_INA0
RXDET
R/W
0x00
7:4
Reserved
3:2
RXDET
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
1:0
Reserved
Set bits to 0.
0x0F
CH0 - S_INA0
EQ
7:0
EQ Control
R/W
0x2F
0x10
Reserved
7:0
Reserved
R/W
0xAD
0x11
Reserved
7:0
Reserved
R/W
0x02
0x12
Reserved
7:0
Reserved
R/W
0x00
0x15
CH1 - S_INB0
RXDET
7:4
Reserved
R/W
0x00
3:2
RXDET
Set bits to 0.
EQ Control - total of 256 levels.
See Table 2: Equalizer Settings.
Set bits to 0.
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
1:0
Reserved
0x16
CH1 - S_INB0
EQ
7:0
EQ Control
R/W
0x2F
EQ Control - total of 256 levels.
See Table 2: Equalizer Settings.
0x17
CH1 - D_OUT0
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
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Set bits to 0.
22
CH1 - D_OUT0
DEM
0x02
7
RXDET STATUS
R
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Observation bit for RXDET CH1 - CHB1.
1: RX = detected
0: RX = not detected
0x19
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x1C
CH2 - S_INA1
RXDET
7:4
Reserved
R/W
0x00
Set bits to 0.
3:2
RXDET
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
1:0
Set bits to 0.
0x1D
CH2 - S_INA1
EQ
7:0
EQ Control
R/W
0x2F
0x1E
Reserved
7:0
Reserved
R/W
0xAD
0x1F
Reserved
7:0
Reserved
R/W
0x02
0x20
Reserved
7:0
Reserved
R/W
0x00
0x23
CH3 - S_INB1
RXDET
7:4
Reserved
R/W
0x00
3:2
RXDET
1:0
Reserved
7:0
EQ Control
0x24
CH3 - S_INB1
EQ
DS100MB203
0x18
EQ Control - total of 256 levels.
See .
Set bits to 0.
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
Set bits to 0.
R/W
23
0x2F
EQ Control - total of 256 levels.
See .
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DS100MB203
0x25
0x26
CH3 - D_OUT1
VOD
CH3 - D_OUT1
DEM
R/W
0xAD
7
Short Circuit
Protection
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
7
RXDET STATUS
R
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
0x02
1: Enable the short circuit protection
0: Disable the short circuit protection
Observation bit for RXDET CH1 - CHB1.
1: RX = detected
0: RX = not detected
0x27
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x2B
CH4 - D_IN0
RXDET
7:4
Reserved
R/W
0x00
Set bits to 0.
3:2
RXDET
1:0
Reserved
7:0
EQ Control
0x2C
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CH4 - D_IN0
EQ
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
Set bits to 0.
R/W
24
0x2F
EQ Control - total of 256 levels.
See Table 2: Equalizer Settings.
0x2E
CH4 - S_OUTA0
VOD
CH4 - S_OUTA0
DEM
R/W
0xAD
7
Short Circuit
Protection
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
7
RXDET STATUS
R
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
0x02
1: Enable the short circuit protection
0: Disable the short circuit protection
Observation bit for RXDET.
1: RX = detected
0: RX = not detected
0x2F
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x32
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x33
Reserved
7:0
Reserved
R/W
0x2F
0x34
CH5 - S_OUTB0
VOD
7
Short Circuit
Protection
R/W
0xAD
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
25
DS100MB203
0x2D
1: Enable the short circuit protection
0: Disable the short circuit protection
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DS100MB203
0x35
CH5 - S_OUTB0
DEM
0x02
7
RXDET STATUS
R
Observation bit for RXDET.
1: RX = detected
0: RX = not detected
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
0x36
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x39
CH6 - D_IN1
RXDET
7:4
Reserved
R/W
0x00
Set bits to 0.
3:2
RXDET
00: Input is high-z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times) then
stops; termination is high-z until detection; once
detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is high-z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET control in Reg_08.
1:0
Reserved
0x3A
CH6 - D_IN1
EQ
7:0
EQ Control
R/W
0x2F
EQ Control - total of 256 levels.
See Table 2: Equalizer Settings.
0x3B
CH6 - S_OUTA1
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
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Set bits to 0.
26
CH6 - S_OUTA1
DEM
0x02
7
RXDET STATUS
R
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Observation bit for RXDET.
1: RX = detected
0: RX = not detected
0x3D
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x40
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x41
Reserved
7:0
Reserved
R/W
0x2F
EQ Control - total of 256 levels.
See Table 2: Equalizer Settings.
0x42
CH7 - S_OUTB1
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
MODE Control
1: PCIe GEN 1/2, 10GE
0: PCIe GEN 3, 10G-KR
Note: override the MODE pin in Reg_08.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
VOD Control
000: 0.6 V
001: 0.7 V
010: 0.8 V
011: 0.9 V
100: 1.0 V
101: 1.1 V (default)
110: 1.2 V
111: 1.3 V
7
RXDET STATUS
R
6:5
MODE STATUS
R
Observation bit for MODE.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
0x43
CH7 - S_OUTB1
DEM
0x02
DS100MB203
0x3C
Observation bit for RXDET.
CH7 - CHA3.
1: RX = detected
0: RX = not detected
0x44
Reserved
7:4
Reserved
R/W
0x00
Set bits to 0.
0x51
Device ID
7:5
VERSION
R
0x46
010'b
4:0
ID
00110'b
27
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DS100MB203
0x5E
0x5F
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Override SEL1,
SEL0 and
INPUT_EN
Control SEL1,
SEL0 and
INPUT_ENl
R/W
0x00
7:3
Reserved
2
Override SEL1 pin
1: Block SEL1 pin control;
use Reg_5F to configure.
0: Allow SEL1 pin control
1
Override SEL0 pin
1: Block SEL0 pin control;
use Reg_5F to configure.
0: Allow SEL0 pin control
0
Override
INPUT_EN pin
1: Block INPUT_EN pin control;
use Reg_5F to configure.
0: Allow INPUT_EN pin control
7:6
SEL1 Control
5:4
SEL0 Control
Select for Lane 0.
00: 0 - selects input S_INB0+/-,
output S_OUTB0+/-.
01: 20kΩ to GND - selects input S_INB0+/-,
output S_OUTA0+/10: FLOAT - selects input S_INA0+/-,
output S_OUTB0+/11: 1 - selects input S_INA0+/-,
output S_OUTA0+/-.
3:2
INPUT_EN Control
00: 0 - Normal Operation, FANOUT is disabled, use
SEL0/1 to select the A or B input/output (see SEL0/1
pin), input always enabled with 50 ohms.
01: 20kΩ to GND - Reserved.
10: FLOAT - AUTO - Use RX Detect, SEL0/1 to
determine which input or output to enable, FANOUT
is disable.
11: 1 - Normal Operation, FANOUT is enabled (both
S_OUT0/1 are ON). Input always enabled with 50
ohms.
1:0
Reserved
Set bits to 0.
R/W
28
0x00
Set bits to 0.
Select for Lane 1.
00: 0 - selects input S_INB1+/-,
output S_OUTB1+/-.
01: 20kΩ to GND - selects input S_INB1+/-,
output S_OUTA1+/10: FLOAT - selects input S_INA1+/-,
output S_OUTB1+/11: 1 - selects input S_INA1+/-,
output S_OUTA1+/-.
GENERAL RECOMMENDATIONS
The DS100MB203 is a high performance circuit capable of
delivering excellent performance. Careful attention must be
paid to the details associated with high-speed design as well
as providing a clean power supply. Refer to the information
below and Revision 4 of the LVDS Owner's Manual for more
detailed information on high speed design tips to address signal integrity design issues.
POWER SUPPLY BYPASSING
Two approaches are recommended to ensure that the
DS100MB203 is provided with an adequate power supply.
First, the supply (VDD) and ground (GND) pins should be
connected to power planes routed on adjacent layers of the
printed circuit board. The layer thickness of the dielectric
should be minimized so that the VDD and GND planes create
a low inductance supply with distributed capacitance. Second, careful attention to supply bypassing through the proper
use of bypass capacitors is required. A 0.1 μF bypass capacitor should be connected to each VDD pin such that the capacitor is placed as close as possible to the DS100MB203.
Smaller body size capacitors can help facilitate proper component placement. Additionally, capacitor with capacitance in
the range of 1 μF to 10 μF should be incorporated in the power
supply bypassing design as well. These capacitors can be
either tantalum or an ultra-low ESR ceramic.
PCB LAYOUT CONSIDERATIONS FOR DIFFERENTIAL
PAIRS
The CML inputs and outputs have been optimized to work with
interconnects using a controlled differential impedance of 85
- 100Ω. It is preferable to route differential lines exclusively on
one layer of the board, particularly for the input traces. The
use of vias should be avoided if possible. If vias must be used,
they should be used sparingly and must be placed symmetrically for each side of a given differential pair. Whenever
differential vias are used the layout must also provide for a
low inductance path for the return currents as well. Route the
29
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DS100MB203
differential signals away from other signals and noise sources
on the printed circuit board. See AN-1187 for additional information on LLP packages.
Applications Information
DS100MB203
Physical Dimensions inches (millimeters) unless otherwise noted
Order Number DS100MB203SQ (Tape and Reel 2000 units)
Order Number DS100MB203SQE (Tape and Reel 250 units)
Package Number SQA54A
(See AN-1187 for PCB Design and Assembly Recommendations)
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30
DS100MB203
Notes
31
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DS100MB203 10.3125 Gbps Dual Lane 2:1/1:2 Mux/Buffer with Equalization and De-Emphasis
Notes
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