TI1 DS100KR401SQ/NOPB Ultra low power, 4 lane (8-channel, bi-directional) repeater for data-rates up to 10.3 gbp Datasheet

DS100KR401
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SNLS395B – JANUARY 2012 – REVISED MARCH 2012
DS100KR401 Ultra Low Power, 4 Lane (8-channel, bi-directional) Repeater for Data-rates
up to 10.3 Gbps
Check for Samples: DS100KR401
FEATURES
DESCRIPTION
•
The DS100KR401 is an extremely low power, high
performance repeater designed to support 4 lane (bidirectional) 10G-KR and other high speed interface
serial protocols up to 10.3 Gbps. The receiver's
continuous time linear equalizer (CTLE) provides a
boost of up to +36 dB at 5 GHz (10.3125 Gbps) in
each of its eight channels and is capable of opening
an input eye that is completely closed due to inter
symbol interference (ISI) induced by interconnect
medium such as long backplanes or cables, hence
enabling host controllers to ensure an error free endto-end link. The transmitter provides a de-emphasis
boost of up to -12 dB and output voltage amplitude
control from 700 mV to 1300 mV to allow maximum
flexibility in the physical placement within the
interconnect channel.
1
2
•
•
•
•
•
•
•
•
•
Comprehensive Product Family:
– DS100KR800: 8-channel, Uni-directional
Repeater
– DS100KR401: 4x Lane, Bi-directional
Repeater
– DS100BR210: 2-channel, Uni-directional
Repeater
– DS100BR111: 1x Lane, Bi-directional
Repeater
4 Lane (8-channel, Bi-directional) Repeater for
4x 10G-KR and Other Serial Standards up to
10.3 Gbps
Transparent Management of 10G-KR (802.3ap)
Link Training Protocol
Low 65 mW/channel (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: 700 mV to
1300 mV
Programmable via Pin Selection, EEPROM or
SMBus Interface
Single Supply Operation Selectable: 2.5V or
3.3V
–40°C to +85°C Operating Temperature Range
3 kV HBM ESD Rating
Flow-thru Pinout in 10mm×5.5mm 54-pin
Leadless WQFN Package
When operating in 10G-KR mode, the DS100KR401
transparently allows the host controller and the end
point to optimize the full link and negotiate transmit
equalizer coefficients as defined in the 802.3ap
standard. This seamless management of the link
training protocol ensures guaranteed system level
interoperability with minimum latency.
With a low power consumption of 65 mW/channel
(typ) and option to turn-off unused channels, the
DS100KR401 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 an external
EEPROM. When operating in the EEPROM mode,
the configuration information is automatically loaded
on power up. This eliminates the need for an external
microprocessor or software driver.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2012, Texas Instruments Incorporated
DS100KR401
SNLS395B – JANUARY 2012 – REVISED MARCH 2012
www.ti.com
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
TYPICAL APPLICATION
10 Gbps KR
ASIC
DS100KR401
10 Gbps KR
ASIC
DS100KR401
Server Card
Application Card
ck
Ba ne
Pla
BLOCK DIAGRAM - DETAIL VIEW OF CHANNEL (1 of 8)
VOD/ DeEMPHASIS
CONTROL
VDD
DEMA/B
SMBus
EQ
INx_n+
OUTBUF
INx_n-
OUTx_n+
OUTx_n-
EQA/B
SMBus
Equalizer CONTROL
2
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DEMA1/SCL
DEMA0/SDA
ENSMB
EQB1/AD2
EQB0/AD3
49
48
47
46
VDD
50
RESET
51
DEMB0/AD1
53
52
DEMB1/AD0
54
PIN DIAGRAM
SMBUS AND CONTROL
OUT_B_0+
1
45
IN_B_0+
OUT_B_0-
2
44
IN_B_0-
OUT_B_1+
3
43
IN_B_1+
OUT_B_1-
4
42
IN_B_1-
OUT_B_2+
5
41
VDD
OUT_B_2-
6
40
IN_B_2+
OUT_B_3+
7
39
IN_B_2-
OUT_B_3-
8
38
IN_B_3+
37
IN_B_3-
DAP = GND
VDD
9
IN_A_0+
10
36
VDD
IN_A_0-
11
35
OUT_A_0+
IN_A_1+
12
34
OUT_A_0-
IN_A_1-
13
33
OUT_A_1+
VDD
14
32
OUT_A_1-
IN_A_2+
15
31
OUT_A_2+
IN_A_2-
16
30
OUT_A_2-
IN_A_3+
17
29
OUT_A_3+
IN_A_3-
18
28
OUT_A_3-
20
21
22
23
24
25
26
27
EQA0
MODE
INPUT_EN
LPBK
VIN
VDD_SEL
SD_THA / READ_EN
ALL_DONE
EQA1
19
Vreg
Figure 1. DS100KR401 Pin Diagram 54 lead
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PIN DESCRIPTIONS (1)
Pin Name
Pin Number
I/O, Type
Pin Description
Differential High Speed I/O's
OUT_B_0+, OUT_B_0,
OUT_B_1+, OUT_B_1,
OUT_B_2+, OUT_B_2,
OUT_B_3+, OUT_B_3-
1, 2,
3, 4,
5, 6,
7, 8
O
Inverting and non-inverting 50Ω driver bank B outputs with de-emphasis.
Compatible with AC coupled CML inputs.
IN_A_0+,
IN_A_1+,
IN_A_2+,
IN_A_3+,
IN_A_0-,
IN_A_1-,
IN_A_2-,
IN_A_3-
10,
12,
15,
17,
11,
13,
16,
18
I
Inverting and non-inverting differential inputs to bank A equalizer. A gated onchip 50Ω termination resistor connects INA_n+ to VDD and INA_n- to VDD
when enabled.
IN_B_0+,
IN_B_1+,
IN_B_2+,
IN_B_3+,
IN_B_0-,
IN_B_1-,
IN_B_2-,
IN_B_3-
45,
43,
40,
38,
44,
42,
39,
37
I
Inverting and non-inverting differential inputs to bank B equalizer. A gated onchip 50Ω termination resistor connects INB_n+ to VDD and INB_n- to VDD
when enabled.
35,
33,
31,
29,
34,
32,
30,
28
O
Inverting and non-inverting 50Ω driver bank A outputs with de-emphasis.
Compatible with AC coupled CML inputs.
I, LVCMOS
System Management Bus (SMBus) enable pin
Tie 1kΩ to VDD = Register Access SMBus Slave mode
FLOAT = Read External EEPROM (Master SMBUS Mode)
Tie 1kΩ to GND = Pin Mode
OUT_A_0+, OUT_A_0,
OUT_A_1+, OUT_A_1,
OUT_A_2+, OUT_A_2,
OUT_A_3+, OUT_A_3-
Control Pins — Shared (LVCMOS)
ENSMB
48
ENSMB = 1 (SMBUS MODE)
SCL
50
I, LVCMOS,
O, OPEN
Drain
ENSMB Master or Slave mode
SMBUS clock input pin is enabled.
Clock output when loading EEPROM configuration (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 (pulldown 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, 4-LEVEL,
LVCMOS
When using an External EEPROM, a transition from high to low starts the
load from the external EEPROM
ENSMB = 0 (PIN MODE)
EQA0, EQA1,
EQB0, EQB1
20, 19, 46, 47
I, 4-LEVEL,
LVCMOS
EQA[1:0] and EQB[1:0] control the level of equalization on the input pins. The
pins are active only when ENSMB is deasserted (low). The 8 channels are
organized into two banks. Bank A is controlled with the EQA[1:0] pins and
bank B is controlled with the EQB[1:0] pins. When ENSMB is high the SMBus
registers provide independent control of each channel. The EQB[1:0] pins are
converted to SMBUS AD2/ AD3 inputs.
See Table 2
DEMA0, DEMA1,
DEMB0, DEMB1
49, 50, 53, 54
I, 4-LEVEL,
LVCMOS
DEMA[1:0] and DEMB[1:0] control the level of de-emphasis of the output
driver when in Gen1/2 mode. The pins are only active when ENSMB is deasserted (low). The 8 channels are organized into two banks. Bank A is
controlled with the DEMA [1:0] pins and bank B is controlled with the
DEMB[1:0] pins. When ENSMB is high the SMBus registers provide
independent control of each channel. The DEMA[1:0] pins are converted to
SMBUS SCL/SDA and DEMB[1:0] pins are converted to AD0, AD1 inputs.
See Table 3
(1)
4
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%.
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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PIN DESCRIPTIONS(1) (continued)
Pin Name
Pin Number
I/O, Type
Pin Description
MODE
21
I, 4-LEVEL,
LVCMOS
Tie 1kΩ to VDD = 10G-KR Mode Operation
Tie 1kΩ to GND = 10G Mode Operation
SD_TH
26
I, 4-LEVEL,
LVCMOS
Controls the internal Signal Detect Threshold
See Table 4
Control Pins — Both Pin and SMBus Modes (LVCMOS)
INPUT_EN
22
I, 4-LEVEL,
LVCMOS
Tie 1kΩ to VDD = Normal Operation
LPBK
23
I, 4-LEVEL,
LVCMOS
Controls the loopback function
Tie 1kΩ to GND = INA_n to OUTB_n loopback
Float = Normal Operation (loopback is disabled)
Tie 1kΩ to VDD = INB_n to OUTA_n loopback
VDD_SEL
25
I, FLOAT
Controls the internal regulator
Float = 2.5V mode
Tie GND = 3.3V mode
RESET
52
I, LVCMOS
LOW = Device is enabled (Normal Operation)
HIGH = Low Power Mode
27
O, LVCMOS
Valid Register Load Status Output
HIGH = External EEPROM load failed
LOW = External EEPROM load passed
VIN
24
Power
In 3.3V mode, feed 3.3V 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
3.3V mode, connect 0.1 uF cap to each VDD pin
GND
DAP
Power
Ground pad (DAP - die attach pad).
Outputs
ALL_DONE
Power
ABSOLUTE MAXIMUM RATINGS
(1) (2)
Supply Voltage (VDD = 2.5V mode)
-0.5V to +2.75V
Supply Voltage (VIN = 3.3V mode)
-0.5V to +4.0V
LVCMOS Input/Output Voltage
-0.5V to +4.0V
CML Input Voltage
-0.5V to (VDD+0.5)
CML Input Current
-30 to +30 mA
Junction Temperature
125°C
Storage Temperature
-40°C to +125°C
Lead Temperature Range Soldering (4 sec.)
+260°C
Derate NJY0054A Package
ESD Rating
52.6mW/°C above +25°C
HBM, STD - JESD22-A114F
5 kV
MM, STD - JESD22-A115-A
150 V
CDM, STD - JESD22-C101-D
Thermal Resistance
1000 V
θJC
11.5°C/W
θJA, No Airflow, 4 layer JEDEC
19.1°C/W
For soldering specifications: see product folder at www.ti.com , and SNOA549
(1)
(2)
“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 specified for a junction temperature range of -40°C to +125°C. Models are validated to Maximum Operating
Voltages only.
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and
specifications.
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RECOMMENDED OPERATING CONDITIONS
Min
Typ
Max
Units
Supply Voltage (2.5V mode)
2.375
2.5
2.625
V
Supply Voltage (3.3V mode)
3.0
3.3
3.6
V
Ambient Temperature
-40
25
+85
°C
3.6
V
100
mVp-p
SMBus (SDA, SCL)
Supply Noise up to 50 MHz
(1)
(1)
Allowed supply noise (mVp-p sine wave) under typical conditions.
ELECTRICAL CHARACTERISTICS (1)
Symbol
Typ (2)
Max
Units
VDD = 2.5 V supply, EQ Enabled,
VOD = 1.0 Vp-p, INPUT_EN = 1, RESET = 0
500
700
mW
VIN = 3.3 V supply, EQ Enabled,
VOD = 1.0 Vp-p, INPUT_EN = 1, RESET = 0
660
900
mW
2.0
3.6
V
0
0.8
V
Parameter
Conditions
Power Dissipation
Min
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
Input High Current with internal
resistors (4–level input pin)
Iil
Input Low Current (RESET pin)
3.3V Mode Operation (VIN = 3.3V)
2.0
VIN = 3.6 V, LVCMOS = 0 V
Input Low Current with internal
resistors (4–level input pin)
V
0.4
V
-15
+15
uA
+20
+150
uA
-15
+15
uA
-160
-40
uA
CML Receiver Inputs (IN_n+, IN_n-)
RLrx-diff
RX package pins plus Si
differential return loss
0.05 GHz - 7.5 GHz
-15
dB
7.5 GHz - 15 GHz
-5
dB
RLrx-cm
Common mode RX return loss
0.05 GHz - 5 GHz
Zrx-dc
RX DC common mode impedance
Tested at VDD = 0
40
50
60
Ω
Zrx-diff-dc
RX DC differntial mode impedance Tested at VDD = 0
80
100
120
Ω
Vrx-diff-dc
Differential RX peak to peak
voltage
0.6
1.2
V
Vrx-signal-detdiff-pp
Signal detect assert level for active SD_TH = F (float), 0101 pattern at 10.3 Gbps
data signal
180
mVp-p
Vrx-idle-detdiff-pp
Signal detect de-assert level for
electrical idle
110
mVp-p
-10
Tested at pins
SD_TH = F (float), 0101 pattern at 10.3 Gbps
dB
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, DEM0 = 1,
DEM1 = 0
0.8
1.0
1.2
Vp-p
Vtx-de-ratio_3.5
TXde-emphasis ratio
VOD = 1.0 Vp-p, DEM0 = 0, DEM1 = R
−3.5
Vtx-de-ratio_6
TX de-emphasis ratio
VOD = 1.0 Vp-p, DEM0 = R, DEM1= R
−6
TTX-HF-DJ-DD
TX Dj > 1.5 MHz
0.15
UI
TTX-HF-DJ-DD
TX RMS jitter < 1.5 MHz
3.0
ps RMS
(1)
(2)
6
dB
dB
The Electrical Characteristics tables list 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.
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.
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ELECTRICAL CHARACTERISTICS(1) (continued)
Symbol
Parameter
Conditions
Min
Typ (2)
TTX-RISE-FALL
Transmitter rise/fall time
20% to 80% of differential output voltage
35
45
TRF-MISMATCH
Transmitter rise/fall mismatch
20% to 80% of differential output voltage
0.01
RLTX-DIFF
Differential return loss
0.05 GHz - 7.5 GHz
-15
dB
7.5 GHz - 15 GHz
-5
dB
RLTX-CM
Common mode return loss
0.05 GHz - 5 GHz
-10
dB
ZTX-DIFF-DC
DC differential TX impedance
100
Ω
VTX-CM-AC-PP
TX AC common mode voltage
VOD = 1.0 Vp-p, DEM0 = 1, DEM1 = 0
ITX-SHORT
Transmitter short circuit current
limit
Total current the transmitter can supply when
shorted to VDD or GND
TPDEQ
Differential propagation delay
EQ = 00,
TLSK
TPPSK
Max
Units
ps
0.1
100
UI
mVpp
20
mA
(3)
200
ps
Lane to lane skew
T = 25C, VDD = 2.5V
25
ps
Part to part propagation delay
skew
T = 25C, VDD = 2.5V
40
ps
DJE1
Residual deterministic jitter at
10.3 Gbps
35” 4 mil FR4, VID = 0.8 Vp-p, PRBS15,
EQ = 1F'h, DEM = 0 dB
0.3
UI
DJE2
Residual deterministic jitter at
10.3 Gbps
10 meters 30 awg cable, VID = 0.8 Vp-p,
PRBS15, EQ = 2F'h, DEM = 0 dB
0.3
UI
Residual deterministic jitter at
10.3 Gbps
20” 4mils FR4, VID = 0.8 Vp-p, PRBS15,
EQ = 00, VOD = 1.0 Vp-p, DEM = −9 dB
0.1
UI
Equalization
De-emphasis
DJD1
(3)
Propagation Delay measurements will change slightly based on the level of EQ selected. EQ = 00 will result in the shortest propagation
delays.
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
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
pull to VDD = 2.5V ± 5%
OR 3.3V ± 10%
2.1
High Power Specification
4
mA
2.375
See
(1)
-200
3.6
V
+200
µA
-15
See
(1) (2)
µA
10
Pullup VDD = 3.3V, See
(1) (2) (3)
Pullup VDD = 2.5V, See
(1) (2) (3)
pF
2000
Ω
1000
Ω
SERIAL BUS INTERFACE TIMING SPECIFICATIONS
FSMB
Bus Operating Frequency
TBUF
Bus Free Time Between Stop and
Start Condition
THD:STA
Hold time after (Repeated) Start
Condition. After this period, the
first clock is generated.
ENSMB = VDD (Slave Mode)
ENSMB = FLOAT (Master Mode)
TSU:STA
(1)
(2)
(3)
280
400
400
kHz
520
kHz
1.3
µs
0.6
µs
0.6
µs
At IPULLUP, Max
Repeated Start Condition Setup
Time
Recommended value.
Recommended maximum capacitance load per bus segment is 400pF.
Maximum termination voltage should be identical to the device supply voltage.
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ELECTRICAL CHARACTERISTICS — SERIAL MANAGEMENT BUS INTERFACE (continued)
Over recommended operating supply and temperature ranges unless other specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
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
1.3
µs
THIGH
Clock High Period
See
tF
Clock/Data Fall Time
See
tR
Clock/Data Rise Time
See
(4)
See
(4) (5)
tPOR
(4)
(5)
Time in which a device must be
operational after power-on reset
(4)
0.6
(4)
50
µs
300
ns
300
ns
500
ms
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.
Specified by Design. Parameter not tested in production.
TIMING DIAGRAMS
(OUT+)
80%
80%
VOD (p-p) = (OUT+) ± (OUT-)
0V
20%
20%
(OUT-)
tRISE
tFALL
Figure 2. CML Output and Rise and FALL Transition Time
+
IN
0V
tPHLD
tPLHD
+
OUT
0V
-
Figure 3. Propagation Delay Timing Diagram
tLOW
tR
tHIGH
SCL
tHD:STA
tBUF
tHD:DAT
tF
tSU:STA
tSU:DAT
tSU:STO
SDA
SP
ST
ST
SP
Figure 4. SMBus Timing Parameters
8
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FUNCTIONAL DESCRIPTIONS
The DS100KR401 is a low power media compensation 4 lane repeater optimized for 10G–KR. The DS100KR401
compensates for lossy FR-4 printed circuit board backplanes and balanced cables. The DS100KR401 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) , the repeater is configurable with external pins. 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. The receiver electrical idle detect threshold is also adjustable via the
SD_TH pin.
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 A or B as in the pin mode
case. Upon assertion of ENSMB the MODE, EQx and DEMx functions revert to register control immediately. The
EQx and DEMx pins are converted to AD0-AD3 SMBus address inputs. The other external control pins remain
active unless their respective registers are written to and the appropriate override bit is set, in which case they
are ignored until ENSMB is driven low (pin mode). On power-up and when ENSMB is driven low all registers are
reset to their default state. If RESET is asserted 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 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 de-Emphasis levels are set by
registers.
The input control pins have been enhanced to have 4 different levels and provide a wider range of control
settings when ENSMB=0.
Table 1. 4–Level Control Pin Settings (1)
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
(1)
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 DS100KR401 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 µF cap is needed at each of 5
VDD pins for power supply de-coupling (total capacitance should be ≤0.5 µF). 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.
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3.3V mode
2.5V mode
VDD_SEL
Enable
VDD_SEL
open
VIN
open
Disable
3.3V
Capacitors can be
either tantalum or an
ultra-low ESR seramic.
Internal
voltage
regulator
2.5V
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
VDD
1 uF
VDD
10 uF
2.5V
1 uF
VIN
10 uF
Internal
voltage
regulator
Capacitors can be
either tantalum or an
ultra-low ESR seramic.
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
Place 0.1 uF close to VDD Pin
Total capacitance should be 7 0.5 uF
Place capcitors close to VDD Pin
Figure 5. 3.3V or 2.5V Supply Connection Diagram
Table 2. Equalizer Settings
Level
EQA1
EQB1
1
2
10
EQA0
EQB0
EQ – 8 bits [7:0]
dB at
1.0 GHz
dB at
3.0 GHz
dB at
5.0 GHz
0
0
0000 0000 = 0x00
1.7
4.2
5.3
FR4 < 5 inch trace
0
R
0000 0001 = 0x01
2.8
6.6
8.7
FR4 5 inch 5–mil trace
3
0
Float
0000 0010 = 0x02
4.1
8.6
10.6
FR4 5 inch 4–mil trace
4
0
1
0000 0011 = 0x03
5.1
9.8
11.7
FR4 10 inch 5–mil trace
5
R
0
0000 0111 = 0x07
6.2
12.4
15.6
FR4 10 inch 4–mil trace
6
R
R
0001 0101 = 0x15
5.1
12.0
16.6
FR4 15 inch 4–mil trace
7
R
Float
0000 1011 = 0x0B
7.7
15.0
18.3
FR4 20 inch 4–mil trace
8
R
1
0000 1111 = 0x0F
8.8
16.5
19.7
FR4 25 to 30 inch 4–mil trace
9
Float
0
0101 0101 = 0x55
6.3
14.8
20.3
FR4 30 inch 4–mil trace
10
Float
R
0001 1111 = 0x1F
9.9
19.2
23.6
FR4 35 inch 4–mil trace
11
Float
Float
0010 1111 = 0x2F
11.3
21.7
25.8
10m, 30awg cable
12
Float
1
0011 1111 = 0x3F
12.4
23.2
27.0
10m – 12m cable
13
1
0
1010 1010 = 0xAA
11.9
24.1
29.1
14
1
R
0111 1111 = 0x7F
13.6
26.0
30.7
15
1
Float
1011 1111 = 0xBF
15.1
28.3
32.7
16
1
1
1111 1111 = 0xFF
16.1
29.7
33.8
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Table 3. De-emphasis and Output Voltage Settings
Level
DEMA1
DEMB1
DEMA0
DEMB0
VOD Vp-p
DEM dB
Inner Amplitude
Vp-p
Suggested Use
1
0
0
0.8
0
0.8
FR4 <5 inch 4–mil trace
2
0
R
0.9
0
0.9
FR4 <5 inch 4–mil trace
3
0
Float
0.9
- 3.5
0.6
FR4 10 inch 4–mil trace
4
0
1
1.0
0
1.0
FR4 <5 inch 4–mil trace
5
R
0
1.0
- 3.5
0.7
FR4 10 inch 4–mil trace
6
R
R
1.0
-6
0.5
FR4 15 inch 4–mil trace
7
R
Float
1.1
0
1.1
FR4 <5 inch 4–mil trace
8
R
1
1.1
- 3.5
0.7
FR4 10 inch 4–mil trace
9
Float
0
1.1
-6
0.6
FR4 15 inch 4–mil trace
10
Float
R
1.2
0
1.2
FR4 <5 inch 4–mil trace
11
Float
Float
1.2
- 3.5
0.8
FR4 10 inch 4–mil trace
12
Float
1
1.2
-6
0.6
FR4 15 inch 4–mil trace
13
1
0
1.3
0
1.3
FR4 <5 inch 4–mil trace
14
1
R
1.3
- 3.5
0.9
FR4 10 inch 4–mil trace
15
1
Float
1.3
-6
0.7
FR4 15 inch 4–mil trace
16
1
1
1.3
-9
0.5
FR4 20 inch 4–mil trace
Table 4. Signal Detect Threshold Level (1)
SD_TH
SMBus REG bit [3:2] and [1:0]
Assert Level (typ)
De-assert Level (typ)
0
10
210 mVp-p
150 mVp-p
R
01
160 mVp-p
100 mVp-p
F (default)
00
180 mVp-p
110 mVp-p
1
11
190 mVp-p
130 mVp-p
(1)
VDD = 2.5V, 25°C and 0101 pattern at 10.3 Gbps
SMBUS Master Mode
The DS100KR401 devices support reading directly from an external EEPROM device by implementing SMBus
Master mode. When using the SMBus master mode, the DS100KR401 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.
• 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 DS100KR401 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
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– 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 DS100KR401 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 DS100KR401 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 DS100KR401 device.
:2000000000001000000407002FAD4002FAD4002FAD4002FAD401805F5A8005F5A8005F5AD8
:200020008005F5A800005454000000000000000000000000000000000000000000000000F6
:20006000000000000000000000000000000000000000000000000000000000000000000080
:20008000000000000000000000000000000000000000000000000000000000000000000060
:2000A000000000000000000000000000000000000000000000000000000000000000000040
:2000C000000000000000000000000000000000000000000000000000000000000000000020
:2000E000000000000000000000000000000000000000000000000000000000000000000000
:200040000000000000000000000000000000000000000000000000000000000000000000A0
12
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Table 5. EEPROM Register Map - Single Device with Default Value
EEPROM Address
Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
CRC EN
Address Map
Present
EEPROM > 256
Bytes
RES
DEVICE
COUNT[3]
DEVICE
COUNT[2]
DEVICE
COUNT[1]
DEVICE
COUNT[0]
0
0
0
0
0
0
0
0
RES
RES
RES
RES
RES
RES
RES
RES
0
0
0
0
0
0
0
0
Max EEPROM
Burst size[7]
Max EEPROM
Burst size[6]
Max EEPROM
Burst size[5]
Max EEPROM
Burst size[4]
Max EEPROM
Burst size[3]
Max EEPROM
Burst size[2]
Max EEPROM
Burst size[1]
Max EEPROM
Burst size[0]
0
0
0
0
0
0
0
0
PWDN_ch7
PWDN_ch6
PWDN_ch5
PWDN_ch4
PWDN_ch3
PWDN_ch2
PWDN_ch1
PWDN_ch0
0
0
0
0
0
0
0
0
RES_1
RES_0
PWDN_INPUTS
PWDN_OSC
Ovrd_RESET
RES
RES
RES
0
0
0
0
0
0
0
0
RES
RES
RES
RES
RES
RES_btb_en
Ovrd_RES
Ovrd_RES
0
0
0
0
0
1
0
0
Ovrd_RES
Ovrd_RES
Ovrd_RES
Ovrd_RES
Ovrd_RES
rx_delay_sel_2
rx_delay_sel_1
rx_delay_sel_0
0
0
0
0
0
1
1
1
RD_delay_sel_3
RD_delay_sel_2
RD_delay_sel_1
RD_delay_sel_0
ch0_Idle_auto
ch0_Idle_sel
ch0_RES_1
ch0_RES_0
0
0
0
0
0
0
0
0
ch0_BST_7
ch0_BST_6
ch0_BST_5
ch0_BST_4
ch0_BST_3
ch0_BST_2
ch0_BST_1
ch0_BST_0
0
0
1
0
1
1
1
1
ch0_Sel_scp
ch0_Sel_mode
ch0_RES_2
ch0_RES_1
ch0_RES_0
ch0_VOD_2
ch0_VOD_1
ch0_VOD_0
1
0
1
0
1
1
0
1
ch0_DEM_2
ch0_DEM_1
ch0_DEM_0
ch0_Slow
ch0_idle_tha_1
ch0_idle_tha_0
ch0_idle_thd_1
ch0_idle_thd_0
0
1
0
0
0
0
0
0
ch1_Idle_auto
ch1_Idle_sel
ch1_RES_1
ch1_RES_0
ch1_BST_7
ch1_BST_6
ch1_BST_5
ch1_BST_4
0
0
0
0
0
0
1
0
ch1_BST_3
ch1_BST_2
ch1_BST_1
ch1_BST_0
ch1_Sel_scp
ch1_Sel_mode
ch1_RES_2
ch1_RES_1
1
1
1
1
1
0
1
0
ch1_RES_0
ch1_VOD_2
ch1_VOD_1
ch1_VOD_0
ch1_DEM_2
ch1_DEM_1
ch1_DEM_0
ch1_Slow
1
1
0
1
0
1
0
0
ch1_idle_tha_1
ch1_idle_tha_0
ch1_idle_thd_1
ch1_idle_thd_0
ch2_Idle_auto
ch2_Idle_sel
ch2_RES_1
ch2_RES_0
0
0
0
0
0
0
0
0
ch2_BST_7
ch2_BST_6
ch2_BST_5
ch2_BST_4
ch2_BST_3
ch2_BST_2
ch2_BST_1
ch2_BST_0
0
0
1
0
1
1
1
1
0
Value
Description
1
Value
Description
2
Value
Description
3
Value
Description
4
Value
Description
5
Value
Description
6
Value
Description
7
Value
Description
8
Value
Description
9
Value
Description
10
Value
Description
11
Value
Description
12
Value
Description
13
Value
Description
14
Value
Description
Value
15
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Table 5. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address
Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch2_Sel_scp
ch2_Sel_mode
ch2_RES_2
ch2_RES_1
ch2_RES_0
ch2_VOD_2
ch2_VOD_1
ch2_VOD_0
1
0
1
0
1
1
0
1
ch2_DEM_2
ch2_DEM_1
ch2_DEM_0
ch2_Slow
ch2_idle_tha_1
ch2_idle_tha_0
ch2_idle_thd_1
ch2_idle_thd_0
0
1
0
0
0
0
0
0
ch3_Idle_auto
ch3_Idle_sel
ch3_RES_1
ch3_RES_0
ch3_BST_7
ch3_BST_6
ch3_BST_5
ch3_BST_4
0
0
0
0
0
0
1
0
ch3_BST_3
ch3_BST_2
ch3_BST_1
ch3_BST_0
ch3_Sel_scp
ch3_Sel_mode
ch3_RES_2
ch3_RES_1
1
1
1
1
1
0
1
0
ch3_RES_0
ch3_VOD_2
ch3_VOD_1
ch3_VOD_0
ch3_DEM_2
ch3_DEM_1
ch3_DEM_0
ch3_Slow
1
1
0
1
0
1
0
0
ch3_idle_tha_1
ch3_idle_tha_0
ch3_idle_thd_1
ch3_idle_thd_0
ovrd_fast_idle
en_high_idle_th_n
en_high_idle_th_s
en_fast_idle_n
0
0
0
0
0
0
0
1
en_fast_idle_s
eqsd_mgain_n
eqsd_mgain_s
ch4_Idle_auto
ch4_Idle_sel
ch4_RXDET_1
ch4_RXDET_0
ch4_BST_7
1
0
0
0
0
0
0
0
ch4_BST_6
ch4_BST_5
ch4_BST_4
ch4_BST_3
ch4_BST_2
ch4_BST_1
ch4_BST_0
ch4_Sel_scp
0
1
0
1
1
1
1
1
ch4_Sel_mode
ch4_RES_2
ch4_RES_1
ch4_RES_0
ch4_VOD_2
ch4_VOD_1
ch4_VOD_0
ch4_DEM_2
0
1
0
1
1
0
1
0
ch4_DEM_1
ch4_DEM_0
ch4_Slow
ch4_idle_tha_1
ch4_idle_tha_0
ch4_idle_thd_1
ch4_idle_thd_0
ch5_Idle_auto
1
0
0
0
0
0
0
0
ch5_Idle_sel
ch5_RES_1
ch5_RES_0
ch5_BST_7
ch5_BST_6
ch5_BST_5
ch5_BST_4
ch5_BST_3
0
0
0
0
0
1
0
1
ch5_BST_2
ch5_BST_1
ch5_BST_0
ch5_Sel_scp
ch5_Sel_mode
ch5_RES_2
ch5_RES_1
ch5_RES_0
1
1
1
1
0
1
0
1
ch5_VOD_2
ch5_VOD_1
ch5_VOD_0
ch5_DEM_2
ch5_DEM_1
ch5_DEM_0
ch5_Slow
ch5_idle_tha_1
1
0
1
0
1
0
0
0
ch5_idle_tha_0
ch5_idle_thd_1
ch5_idle_thd_0
ch6_Idle_auto
ch6_Idle_sel
ch6_RES_1
ch6_RES_0
ch6_BST_7
0
0
0
0
0
0
0
0
ch6_BST_6
ch6_BST_5
ch6_BST_4
ch6_BST_3
ch6_BST_2
ch6_BST_1
ch6_BST_0
ch6_Sel_scp
0
1
0
1
1
1
1
1
ch6_Sel_mode
ch6_RES_2
ch6_RES_1
ch6_RES_0
ch6_VOD_2
ch6_VOD_1
ch6_VOD_0
ch6_DEM_2
0
1
0
1
1
0
1
0
16
Value
Description
17
Value
Description
18
Value
Description
19
Value
Description
20
Value
Description
21
Value
Description
22
Value
Description
23
Value
Description
24
Value
Description
25
Value
Description
26
Value
Description
27
Value
Description
28
Value
Description
29
Value
Description
30
Value
Description
Value
14
31
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Table 5. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address
Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch6_DEM_1
ch6_DEM_0
ch6_Slow
ch6_idle_tha_1
ch6_idle_tha_0
ch6_idle_thd_1
ch6_idle_thd_0
ch7_Idle_auto
1
0
0
0
0
0
0
0
ch7_Idle_sel
ch7_RES_1
ch7_RES_0
ch7_BST_7
ch7_BST_6
ch7_BST_5
ch7_BST_4
ch7_BST_3
0
0
0
0
0
1
0
1
ch7_BST_2
ch7_BST_1
ch7_BST_0
ch7_Sel_scp
ch7_Sel_mode
ch7_RES_2
ch7_RES_1
ch7_RES_0
1
1
1
1
0
1
0
1
ch7_VOD_2
ch7_VOD_1
ch7_VOD_0
ch7_DEM_2
ch7_DEM_1
ch7_DEM_0
ch7_Slow
ch7_idle_tha_1
1
0
1
0
1
0
0
0
ch7_idle_tha_0
ch7_idle_thd_1
ch7_idle_thd_0
iph_dac_ns_1
iph_dac_ns_0
ipp_dac_ns_1
ipp_dac_ns_0
ipp_dac_1
0
0
0
0
0
0
0
0
ipp_dac_0
RD23_67
RD01_45
RD_PD_ovrd
RD_Sel_test
RD_RESET_ovrd
PWDB_input_DC
DEM_VOD_ovrd
0
0
0
0
0
0
0
0
DEM_ovrd_N2
DEM_ovrd_N1
DEM_ovrd_N0
VOD_ovrd_N2
VOD_ovrd_N1
VOD_ovrd_N0
SPARE0
SPARE1
0
1
0
1
0
1
0
0
DEM__ovrd_S2
DEM__ovrd_S1
DEM_ovrd_S0
VOD_ovrd_S2
VOD_ovrd_S1
VOD_ovrd_S0
SPARE0
SPARE1
0
1
0
1
0
1
0
0
32
Value
Description
33
Value
Description
34
Value
Description
35
Value
Description
36
Value
Description
37
Value
Description
38
Value
Description
Value
39
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Table 6. Example of EEPROM for 4 Devices Using 2 Address Maps (1)
EEPROM Address
Address (Hex)
EEPROM Data
Comments
0
00
0x43
CRC_EN = 0, Address Map = 1, >256 bytes = 0, Device Count[3:0] = 3
1
01
0x00
2
02
0x08
EEPROM Burst Size
3
03
0x00
CRC not used
4
04
0x0B
Device 0 Address Location
5
05
0x00
CRC not used
6
06
0x0B
Device 1 Address Location
7
07
0x00
CRC not used
8
08
0x30
Device 2 Address Location
9
09
0x00
CRC not used
10
0A
0x30
Device 3 Address Location
11
0B
0x00
Begin Device 0, 1 - Address Offset 3
12
0C
0x00
13
0D
0x04
14
0E
0x07
15
0F
0x00
16
10
0x00
EQ CHB0 = 00
17
11
0xAB
VOD CHB0 = 1.0V
18
12
0x00
DEM CHB0 = 0 (0dB)
19
13
0x00
EQ CHB1 = 00
20
14
0x0A
VOD CHB1 = 1.0V
21
15
0xB0
DEM CHB1 = 0 (0dB)
22
16
0x00
23
17
0x00
EQ CHB2 = 00
24
18
0xAB
VOD CHB2 = 1.0V
25
19
0x00
DEM CHB2 = 0 (0dB)
26
1A
0x00
EQ CHB3 = 00
27
1B
0x0A
VOD CHB3 = 1.0V
28
1C
0xB0
DEM CHB3 = 0 (0dB)
29
1D
0x01
30
1E
0x80
31
1F
0x01
EQ CHA0 = 00
32
20
0x56
VOD CHA0 = 1.0V
33
21
0x00
DEM CHA0 = 0 (0dB)
34
22
0x00
EQ CHA1 = 00
35
23
0x15
VOD CHA1 = 1.0V
36
24
0x60
DEM CHA1 = 0 (0dB)
37
25
0x00
38
26
0x01
EQ CHA2 = 00
39
27
0x56
VOD CHA2 = 1.0V
40
28
0x00
DEM CHA2 = 0 (0dB)
41
29
0x00
EQ CHA3 = 00
42
2A
0x15
VOD CHA3 = 1.0V
43
2B
0x60
DEM CHA3 = 0 (0dB)
44
2C
0x00
45
2D
0x00
(1)
16
CRC_EN = 0, Address Map = 1, >256 byte = 0, Device Count[3:0] = 3. This example has all 8–channels set to EQ = 00 (min boost),
VOD = 1.0V, DEM = 0 (0dB) and multiple device can point to the same address map.
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Table 6. Example of EEPROM for 4 Devices Using 2 Address Maps(1) (continued)
EEPROM Address
Address (Hex)
EEPROM Data
46
2E
0x54
Comments
47
2F
0x54
End Device 0, 1 - Address Offset 39
48
30
0x00
Begin Device 2, 3 - Address Offset 3
49
31
0x00
50
32
0x04
51
33
0x07
52
34
0x00
53
35
0x00
EQ CHB0 = 00
54
36
0xAB
VOD CHB0 = 1.0V
55
37
0x00
DEM CHB0 = 0 (0dB)
56
38
0x00
EQ CHB1 = 00
57
39
0x0A
VOD CHB1 = 1.0V
58
3A
0xB0
DEM CHB1 = 0 (0dB)
59
3B
0x00
60
3C
0x00
EQ CHB2 = 00
61
3D
0xAB
VOD CHB2 = 1.0V
62
3E
0x00
DEM CHB2 = 0 (0dB)
63
3F
0x00
EQ CHB3 = 00
64
40
0x0A
VOD CHB3 = 1.0V
65
41
0xB0
DEM CHB3 = 0 (0dB)
66
42
0x01
67
43
0x80
68
44
0x01
EQ CHA0 = 00
69
45
0x56
VOD CHA0 = 1.0V
70
46
0x00
DEM CHA0 = 0 (0dB)
71
47
0x00
EQ CHA1 = 00
72
48
0x15
VOD CHA1 = 1.0V
73
49
0x60
DEM CHA1 = 0 (0dB)
74
4A
0x00
75
4B
0x01
EQ CHA2 = 00
76
4C
0x56
VOD CHA2 = 1.0V
77
4D
0x00
DEM CHA2 = 0 (0dB)
78
4E
0x00
EQ CHA3 = 00
79
4F
0x15
VOD CHA3 = 1.0V
80
50
0x60
DEM CHA3 = 0 (0dB)
81
51
0x00
82
52
0x00
83
53
0x54
84
54
0x54
End Device 2, 3 - Address Offset 39
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 DS100KR401 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 DS100KR401 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.
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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
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:
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.
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.
18
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WRITING A REGISTER
To
1.
2.
3.
4.
5.
6.
7.
write a register, the following protocol is used (see SMBus 2.0 specification).
The Host drives a START condition, the 7-bit SMBus address, and a “0” indicating a WRITE.
The Device (Slave) drives the ACK bit (“0”).
The Host drives the 8-bit Register Address.
The Device drives an ACK bit (“0”).
The Host drive the 8-bit data byte.
The Device drives an ACK bit (“0”).
The Host drives a STOP condition.
The WRITE transaction is completed, the bus goes IDLE and communication with other SMBus devices may
now occur.
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.
Table 8. SMBUS Slave Mode Register Map
Address
Register Name
Bit (s) Field
Type
Default
Description
0x00
Observation,
Reset
7
Reserved
R/W
0x00
Set bit to 0.
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 resettting the registers; self
clearing.
0
Reset
R/W
SMBus Reset
1: Reset registers to default value; self clearing.
7:0
PWDN CHx
R/W
0x01
PWDN Channels
0x00
Power Down per Channel
[7]: CH7 – CHA_3
[6]: CH6 – CHA_2
[5]: CH5 – CHA_1
[4]: CH4 – CHA_0
[3]: CH3 – CHB_3
[2]: CH2 – CHB_2
[1]: CH1 – CHB_1
[0]: CH0 – CHB_0
00'h = all channels enabled
FF'h = all channels disabled
Note: override RESET pin.
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x02
Override RESET,
LPBK Control
7:6
Reserved
R/W
0x00
Set bits to 0.
5:4
LPBK Control
00:
01:
10:
11:
3:1
Reserved
Set bits to 0.
0
Override RESET
1: Block RESET pin control
0: Allow RESET pin control
Use LPBK pin control
INA to OUTB loopback
INB to OUTA loopback
Disable loopback and ignore LPBK pin.
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.
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
Reserved
6
Override SD_TH
1: Block SD_TH pin control
0: Allow SD_TH pin control
5:2
Reserved
Set bits to 0.
1
Override DEM
1: Block DEM pin control
0: Allow DEM pin control
0x08
Override
Pin Control
Set bits to 0.
R/W
0x00
Set bit to 0.
0
Reserved
0x0E
CH0 - CHB0
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x0F
CH0 - CHB0
EQ
7:0
EQ Control
R/W
0x2F
IB0 EQ Control - total of 256 levels.
See Table 2.
0x10
CH0 - CHB0
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OB0 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH0 - CHB0.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OB0 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
0x11
20
CH0 - CHB0
DEM
Set bit to 0.
0x02
Observation bit for CH0 - CHB0.
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x12
CH0 - CHB0
IDLE Threshold
7:4
Reserved
R/W
0x00
Set bits to 0.
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x15
CH1 - CHB1
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x16
CH1 - CHB1
EQ
7:0
EQ Control
R/W
0x2F
IB1 EQ Control - total of 256 levels. See Table 2.
0x17
CH1 - CHB1
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OB1 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH1 - CHB1.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OB1 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x18
0x19
CH1 - CHB1
DEM
CH1 - CHB1
IDLE Threshold
0x02
0x00
Observation bit for CH1 - CHB1.
Set bits to 0.
0x1C
CH2 - CHB2
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x1D
CH2 - CHB2
EQ
7:0
EQ Control
R/W
0x2F
IB2 EQ Control - total of 256 levels. See Table 2.
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x1E
CH2 - CHB2
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OB2 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH2 - CHB2.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OB2 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x1F
0x20
CH2 - CHB2
DEM
CH2 - CHB2
IDLE Threshold
0x02
0x00
Observation bit for CH2 - CHB2.
Set bits to 0.
0x23
CH3 - CHB3
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x24
CH3 - CHB3
EQ
7:0
EQ Control
R/W
0x2F
IB3 EQ Control - total of 256 levels. See Table 2.
0x25
CH3 - CHB3
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OB0 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
22
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x26
CH3 - CHB3
DEM
7
STATUS
R
0x02
Observation bit for CH3 - CHB3.
6:5
STATUS
R
Observation bit for CH3 - CHB3.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OB3 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x27
CH3 - CHB3
IDLE Threshold
0x00
Set bits to 0.
0x2B
CH4 - CHA0
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x2C
CH4 - CHA0
EQ
7:0
EQ Control
R/W
0x2F
IA0 EQ Control - total of 256 levels.
See Table 2.
0x2D
CH4 - CHA0
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OA0 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH4 - CHA0.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OA0 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
0x2E
CH4 - CHA0
DEM
0x02
Observation bit for CH4 - CHA0.
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x2F
CH4 - CHA0
IDLE Threshold
7:4
Reserved
R/W
0x00
Set bits to 0.
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x32
CH5 - CHA1
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x33
CH5 - CHA1
EQ
7:0
EQ Control
R/W
0x2F
IA1 EQ Control - total of 256 levels. See Table 2.
0x34
CH5 - CHA1
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OA1 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH5 - CHA1.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OA1 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x35
0x36
CH5 - CHA1
DEM
CH5 - CHA1
IDLE Threshold
0x02
0x00
Observation bit for CH5 - CHA1.
Set bits to 0.
0x39
CH6 - CHA2
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x3A
CH6 - CHA2
EQ
7:0
EQ Control
R/W
0x2F
IA2 EQ Control - total of 256 levels. See Table 2.
24
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x3B
CH6 - CHA2
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OA2 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
STATUS
R
6:5
STATUS
R
Observation bit for CH6 - CHA2.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OA2 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
0x3C
0x3D
CH6 - CHA2
DEM
CH6 - CHA2
IDLE Threshold
0x02
0x00
Observation bit for CH6 - CHA2.
Set bits to 0.
0x40
CH7 - CHA3
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0.
0x41
CH7 - CHA3
EQ
7:0
EQ Control
R/W
0x2F
IA3 EQ Control - total of 256 levels. See Table 2.
0x42
CH7 - CHA3
VOD
7
Short Circuit
Protection
R/W
0xAD
1: Enable the short circuit protection
0: Disable the short circuit protection
6
Reserved
Set bit to 0.
5:3
Reserved
Set bits to default value - 101.
2:0
VOD Control
OA3 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
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25
DS100KR401
SNLS395B – JANUARY 2012 – REVISED MARCH 2012
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Table 8. SMBUS Slave Mode Register Map (continued)
Address
Register Name
Bit (s) Field
Type
Default
Description
0x43
CH7 - CHA3
DEM
7
STATUS
R
0x02
Observation bit for CH7 - CHA3.
6:5
STATUS
R
Observation bit for CH7 - CHA3.
4:3
Reserved
R/W
Set bits to 0.
2:0
DEM Control
R/W
OA3 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
7:4
Reserved
R/W
3:2
IDLE thd
De-assert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: override the SD_TH pin.
1:0
IDLE tha
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: override the SD_TH pin.
7:5
VERSION
4:0
ID
0x44
0x51
26
CH7 - CHA3
IDLE Threshold
Device ID
R
0x00
0x44
Set bits to 0.
010'b
00100'b
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SNLS395B – JANUARY 2012 – REVISED MARCH 2012
APPLICATIONS INFORMATION
GENERAL RECOMMENDATIONS
The DS100KR401 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.
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 differential signals away from other signals and noise sources on the printed circuit board. See AN1187 (SNOA401) for additional information on WQFN packages.
20 mils
EXTERNAL MICROSTRIP
100 mils
20 mils
INTERNAL STRIPLINE
VDD
VDD
18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
19
54
20
53
21
52
51
22
BOTTOM OF PKG
23
VDD
50
GND
24
49
25
48
26
47
27
46
28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45
VDD
VDD
Figure 6. Typical Routing Options
The graphic shown above depicts different transmission line topologies which can be used in various
combinations to achieve the optimal system performance. Impedance discontinuities at the differential via can be
minimized or eliminated by increasing the swell around each hole and providing for a low inductance return
current path. When the via structure is associated with thick backplane PCB, further optimization such as back
drilling is often used to reduce the deterimential high frequency effects of stubs on the signal path.
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DS100KR401
SNLS395B – JANUARY 2012 – REVISED MARCH 2012
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POWER SUPPLY BYPASSING
Two approaches are recommended to ensure that the DS100KR401 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 DS100KR401. Smaller
body size capacitors can help facilitate proper component placement. In the case of 3.3V mode operation with
the internal LDO regulator, recommend using capacitors with capacitance in the range of 1.0 μF to 10 μF should
be incorporated in the power supply bypassing design for the VIN pin. These capacitors should be ultra-low ESR
ceramic.
28
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SNLS395B – JANUARY 2012 – REVISED MARCH 2012
TYPICAL CHARACTERISTICS
Typical Performance Curves Characteristics
640.0
VDD = 2.625V
620.0
VDD = 2.5V
600.0
VDD = 2.375V
PD (mW)
580.0
560.0
540.0
520.0
500.0
480.0
T = 25°C
460.0
440.0
420.0
0.8
0.9
1
1.1
1.2
1.3
VOD (Vp-p)
Figure 7. Power Dissipation (PD) vs. Output Differential Voltage (VOD)
1021
T = 25°C
VOD (mVp-p)
1019
1016
1013
1010
1007
2.375
2.5
2.625
VDD (V)
Figure 8. Output Differential Voltage (VOD = 1.0 Vp-p) vs. Supply Voltage (VDD)
1020
VDD = 2.5V
VOD (mVp-p)
1018
1016
1014
1012
- 40
-15
10
35
60
85
TEMPERATURE (°C)
Figure 9. Output Differential Voltage (VOD = 1.0 Vp-p) vs. Temperature
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DS100KR401
SNLS395B – JANUARY 2012 – REVISED MARCH 2012
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TYPICAL CHARACTERISTICS (continued)
Typical Performance Eye Diagrams Characteristics
Pattern
Generator
TL
Lossy Channel
VID = 1.0 Vp-p,
DE = 0 dB
10.3125 Gb/s,
PRBS23
IN
DS100KR401
OUT
Scope
BW = 50 GHz
Figure 10. Test Setup Connections Diagram
Figure 11. TL = 20 inch 4–mil FR4 trace,
DS100KR401 settings: EQ[1:0] = R, R = 15'h, DEM[1:0] = float, float
Figure 12. TL = 30 inch 4–mil FR4 trace,
DS100KR401 settings: EQ[1:0] = float, R = 1F'h, DEM[1:0] = float, float
Pattern
Generator
VID = 1.0 Vp-p,
DE = -9 dB
10.3125 Gb/s,
PRBS23
TL1
Lossy Channel
IN
DS100KR401
OUT
TL2
Lossy Channel
Scope
BW = 50 GHz
Figure 13. Test Setup Connections Diagram
30
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SNLS395B – JANUARY 2012 – REVISED MARCH 2012
TYPICAL CHARACTERISTICS (continued)
Figure 14. TL1 = 20 inch 4–mil FR4 trace, TL2 = 15 inch 4–mil FR4 trace,
DS100KR401 settings: EQ[1:0] = R, R = 15'h, DEM[1:0] = float, float
Figure 15. TL1 = 30 inch 4–mil FR4 trace, TL2 = 15 inch 4–mil FR4 trace,
DS100KR401 settings: EQ[1:0] = float, R = 1F'h, DEM[1:0] = float, float
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PACKAGE OPTION ADDENDUM
www.ti.com
11-Apr-2013
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
(2)
MSL Peak Temp
Op Temp (°C)
Top-Side Markings
(3)
(4)
DS100KR401SQ/NOPB
ACTIVE
WQFN
NJY
54
2000
Green (RoHS
& no Sb/Br)
CU SN
Level-2-260C-1 YEAR
-40 to 85
DS100KR401SQ
DS100KR401SQE/NOPB
ACTIVE
WQFN
NJY
54
250
Green (RoHS
& no Sb/Br)
CU SN
Level-2-260C-1 YEAR
-40 to 85
DS100KR401SQ
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
Multiple Top-Side Markings will be inside parentheses. Only one Top-Side Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a
continuation of the previous line and the two combined represent the entire Top-Side Marking for that device.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
Samples
PACKAGE MATERIALS INFORMATION
www.ti.com
26-Mar-2013
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
DS100KR401SQ/NOPB
WQFN
NJY
54
2000
330.0
16.4
5.8
10.3
1.0
12.0
16.0
Q1
DS100KR401SQE/NOPB
WQFN
NJY
54
250
178.0
16.4
5.8
10.3
1.0
12.0
16.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
26-Mar-2013
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
DS100KR401SQ/NOPB
WQFN
NJY
54
2000
367.0
367.0
38.0
DS100KR401SQE/NOPB
WQFN
NJY
54
250
213.0
191.0
55.0
Pack Materials-Page 2
PACKAGE OUTLINE
NJY0054A
WQFN
SCALE 2.000
WQFN
5.6
5.4
B
A
PIN 1 INDEX AREA
0.5
0.3
0.3
0.2
10.1
9.9
DETAIL
OPTIONAL TERMINAL
TYPICAL
0.8 MAX
C
SEATING PLANE
2X 4
SEE TERMINAL
DETAIL
3.51±0.1
19
(0.1)
27
28
18
50X 0.5
7.5±0.1
2X
8.5
1
45
54
PIN 1 ID
(OPTIONAL)
46
54X
54X
0.5
0.3
0.3
0.2
0.1
0.05
C A
C
B
4214993/A 07/2013
NOTES:
1. All linear dimensions are in millimeters. Dimensions in parenthesis are for reference only. Dimensioning and tolerancing per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for thermal and mechanical performance.
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EXAMPLE BOARD LAYOUT
NJY0054A
WQFN
WQFN
(3.51)
SYMM
54X (0.6)
54
54X (0.25)
SEE DETAILS
46
1
45
50X (0.5)
(7.5)
SYMM
(9.8)
(1.17)
TYP
2X
(1.16)
28
18
( 0.2) TYP
VIA
19
27
(1) TYP
(5.3)
LAND PATTERN EXAMPLE
SCALE:8X
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
METAL
SOLDER MASK
OPENING
SOLDER MASK
OPENING
NON SOLDER MASK
DEFINED
(PREFERRED)
METAL
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4214993/A 07/2013
NOTES: (continued)
4. This package is designed to be soldered to a thermal pad on the board. For more information, refer to QFN/SON PCB application note
in literature No. SLUA271 (www.ti.com/lit/slua271).
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EXAMPLE STENCIL DESIGN
NJY0054A
WQFN
WQFN
SYMM
METAL
TYP
(0.855) TYP
46
54
54X (0.6)
54X (0.25)
1
45
50X (0.5)
(1.17)
TYP
SYMM
(9.8)
12X (0.97)
18
28
19
27
12X (1.51)
(5.3)
SOLDERPASTE EXAMPLE
BASED ON 0.125mm THICK STENCIL
EXPOSED PAD
67% PRINTED SOLDER COVERAGE BY AREA
SCALE:10X
4214993/A 07/2013
NOTES: (continued)
5. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
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