TI SN65LV1023A-EP

SN65LV1023A-EP
SN65LV1224B-EP
www.ti.com
SGLS358 – SEPTEMBER 2006
10-MHz To 66-MHz, 10:1 LVDS SERIALIZER/DESERIALIZER
•
FEATURES
•
•
•
•
•
(1)
Controlled Baseline
– One Assembly/Test Site, One Fabrication
Site
Extended Temperature Performance of –55°C
to 125°C
Enhanced Diminishing Manufacturing
Sources (DMS) Support
Enhanced Product-Change Notification
Qualification Pedigree (1)
Component qualification in accordance with JEDEC and
industry standards to ensure reliable operation over an
extended temperature range. This includes, but is not limited
to, Highly Accelerated Stress Test (HAST) or biased 85/85,
temperature cycle, autoclave or unbiased HAST,
electromigration, bond intermetallic life, and mold compound
life. Such qualification testing should not be viewed as
justifying use of this component beyond specified
performance and environmental limits.
•
•
•
•
•
•
•
•
100-Mbps to 660-Mbps Serial LVDS Data
Payload Bandwidth at 10-MHz to 66-MHz
System Clock
Pin-Compatible Superset of
DS92LV1023/DS92LV1224
Chipset (Serializer/Deserializer) Power
Consumption <450 mW (Typ) at 66 MHz
Synchronization Mode for Faster Lock
Lock Indicator
No External Components Required for PLL
28-Pin SSOP and Space Saving 5 × 5 mm
QFN Packages Available
Programmable Edge Trigger on Clock
Flow-Through Pinout for Easy PCB Layout
DESCRIPTION
The SN65LV1023A serializer and SN65LV1224B deserializer comprise a 10-bit serdes chipset designed to
transmit and receive serial data over LVDS differential backplanes at equivalent parallel word rates from 10 MHz
to 66 MHz. Including overhead, this translates into a serial data rate between 120-Mbps and 792-Mbps payload
encoded throughput.
Upon power up, the chipset link can be initialized via a synchronization mode with internally generated SYNC
patterns or the deserializer can be allowed to synchronize to random data. By using the synchronization mode,
the deserializer establishes lock within specified, shorter time parameters.
The device can be entered into a power-down state when no data transfer is required. Alternatively, a mode is
available to place the output pins in the high-impedance state without losing PLL lock.
The SN65LV1023A and SN65LV1224B are characterized for operation over ambient air temperature of –55°C to
125°C.
ORDERING INFORMATION
TA
(1)
PACKAGE (1)
ORDERABLE PART NUMBER
TOP-SIDE MARKING
-55°C to 125°C
SSOP - DB
Reel of 2000
SN65LV1023AMDBREP
LV1023AMEP
-55°C to 125°C
SSOP - DB
Reel of 2000
SN65LV1224BMDBREP
LV1224BMEP
Package drawings, standard packing quantities, thermal data, symbolization, and PCB design guidelines are available at
www.ti.com/sc/package.
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.
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 © 2006, Texas Instruments Incorporated
SN65LV1023A-EP
SN65LV1224B-EP
www.ti.com
SGLS358 – SEPTEMBER 2006
SYNC1
SYNC2
DIN0
DIN1
DIN2
DIN3
DIN4
DIN5
DIN6
DIN7
DIN8
DIN9
TCLK_R/F
TCLK
1
28
2
27
3
26
4
25
5
24
6
23
7 DB Package 22
SN65LV1023A
8
21
Serializer
9
20
10
19
11
18
12
17
13
16
14
15
AGND
RCLK_R/F
REFCLK
AVCC
RI+
RI−
PWRDN
REN
RCLK
LOCK
AVCC
AGND
AGND
DGND
DVCC
DVCC
AVCC
AGND
PWRDN
AGND
DO+
DO−
AGND
DEN
AGND
AVCC
DGND
DGND
1
28
2
27
3
26
4
25
5
24
6
23
DB Package 22
7
SN65LV1224B
8
21
Deserializer
9
20
10
19
11
18
12
17
13
16
14
15
ROUT0
ROUT1
ROUT2
ROUT3
ROUT4
DVCC
DGND
DVCC
DGND
ROUT5
ROUT6
ROUT7
ROUT8
ROUT9
BLOCK DIAGRAMS
SN65LV1023A
SN65LV1224B
TCLK
(10 MHz to
66 MHz)
PLL
Timing /
Control
Y+
A−
Y−
DEN
Clock
Recovery
SYNC1
SYNC2
2
PLL
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10
Output Latch
A+
Serial-to-Parallel
TCLK_R/F
Input Latch
DIN
Parallel-to-Serial
LVDS
10
Timing /
Control
DOUT
REFCLK
REN
LOCK
RCLK_R/F
RCLK
(10 MHz to
66 MHz)
SN65LV1023A-EP
SN65LV1224B-EP
www.ti.com
SGLS358 – SEPTEMBER 2006
FUNCTIONAL DESCRIPTION
The SN65LV1023A and SN65LV1224B are a 10-bit serializer/deserializer chipset designed to transmit data over
differential backplanes or unshielded twisted pair (UTP) at clock speeds from 10 MHz to 66 MHz. The chipset
has five states of operation: initialization mode, synchronization mode, data transmission mode, power-down
mode, and high-impedance mode. The following sections describe each state of operation.
SYNCHRONIZATION-PATTERN GENERATION (SN65LV1023A)
The synchronization-pattern generation is designed to work, as follows:
After SYNC1 or SYNC2 is held high for at least 6T (T = 1 refclk cycle), the SYNC pattern is generated on the
serial line for 1026T. During this 1026-cycle SYNC pattern transmission, it is not required that SYNC1 or SYNC2
be held high.
There are two different cases in which this SYNC pattern generation might be used:
1. SYNC1 or SYNC2 is held high once at least 6T, but no more than 1026T:
In this case, the sync-pattern generation should generate 1026T of SYNC pattern only once, and the data
that follows the SYNC pattern on the serial line should reflect the parallel inputs. In this scenario, the sync
pattern generation is working as it is designed.
2. SYNC1 or SYNC2 is held high continuously at least 1038T (6T to invoke the first series of SYNC pattern,
and 1026T, which is the duration of the first series of the SYNC pattern, and 6T to invoke the second series
of the SYNC pattern):
If the sync-pattern generator operates as it is intended, the user should be able to observe the continuous
SYNC pattern on the serial line. For example, if the SYNC1 or SYNC2 is held high for 1039T, a user can
see the SYNC pattern being generated continuously for 2052T (=1026T+1026T). However, as shown in
Figure 1, the device behaves in a way that, if the SYNC1 or SYNC2 is held high for more than 1038T, it
sends out 1028T of SYNC pattern, plus 4T of data (which reflects the data that is present on the parallel
input at that time) and another 1026T of SYNC pattern. Figure 1 basically shows how the data on the serial
line would be affected if the SYNC1 or SYNC2 is held for an extended period of time.
Figure 1. Sync-Pattern Generation
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FUNCTIONAL DESCRIPTION (continued)
INITIALIZATION MODE
Initialization of both devices must occur before data transmission can commence. Initialization refers to
synchronization of the serializer and deserializer PLLs to local clocks.
When VCC is applied to the serializer and/or deserializer, the respective outputs enter the high-impedance state,
while on-chip power-on circuitry disables internal circuitry. When VCC reaches 2.45 V, the PLL in each device
begins locking to a local clock. For the serializer, the local clock is the transmit clock (TCLK) provided by an
external source. For the deserializer, a local clock must be applied to the REFCLK pin. The serializer outputs
remain in the high-impedance state, while the PLL locks to the TCLK.
SYNCHRONIZATION MODE
The deserializer PLL must synchronize to the serializer in order to receive valid data. Synchronization can be
accomplished in one of two ways:
• Rapid Synchronization: The serializer has the capability to send specific SYNC patterns consisting of six
ones and six zeros switching at the input clock rate. The transmission of SYNC patterns enables the
deserializer to lock to the serializer signal within a deterministic time frame. This transmission of SYNC
patterns is selected via the SYNC1 and SYNC2 inputs on the serializer. Upon receiving valid SYNC1 or
SYNC2 pulse (wider than 6 clock cycles), 1026 cycles of SYNC pattern are sent.
When the deserializer detects edge transitions at the LVDS input, it attempts to lock to the embedded clock
information. The deserializer LOCK output remains high while its PLL locks to the incoming data or SYNC
patterns present on the serial input. When the deserializer locks to the LVDS data, the LOCK output goes
low. When LOCK is low, the deserializer outputs represent incoming LVDS data. One approach is to tie the
deserializer LOCK output directly to SYNC1 or SYNC2.
• Random-Lock Synchronization: The deserializer can attain lock to a data stream without requiring the
serializer to send special SYNC patterns. This allows the SN65LV1224B to operate in open-loop
applications. Equally important is the deserializer’s ability to support hot insertion into a running backplane.
In the open-loop or hot-insertion case, it is assumed the data stream is essentially random. Therefore,
because lock time varies due to data stream characteristics, the exact lock time cannot be predicted. The
primary constraint on the random lock time is the initial phase relation between the incoming data and the
REFCLK when the deserializer powers up.
The data contained in the data stream can also affect lock time. If a specific pattern is repetitive, the deserializer
could enter false lock—falsely recognizing the data pattern as the start/stop bits. This is referred to as repetitive
multitransition (RMT); see Figure 2 for RMT examples. This occurs when more than one low-high transition
takes place per clock cycle over multiple cycles. In the worst case, the deserializer could become locked to the
data pattern rather than the clock. Circuitry within the deserializer can detect that the possibility of false lock
exists. Upon detection, the circuitry prevents the LOCK output from becoming active until the potential false lock
pattern changes. Notice that the RMT pattern only affects the deserializer lock time, and once the deserializer is
in lock, the RMT pattern does not affect the deserializer state as long as the same data boundary happens each
cycle. The deserializer does not go into lock until it finds a unique four consecutive cycles of data boundary
(stop/start bits) at the same position.
The deserializer stays in lock until it cannot detect the same data boundary (stop/start bits) for four consecutive
cycles. Then the deserializer goes out of lock and hunts for the new data boundary (stop/start bits). In the event
of loss of synchronization, the LOCK pin output goes high and the outputs (including RCLK) enter a
high-impedance state. The user’s system should monitor the LOCK pin in order to detect a loss of
synchronization. Upon detection of loss of lock, sending sync patterns for resynchronization is desirable if
reestablishing lock within a specific time is critical. However, the deserializer can lock to random data as
previously noted.
4
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SN65LV1224B-EP
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SGLS358 – SEPTEMBER 2006
FUNCTIONAL DESCRIPTION (continued)
DIN0 Held Low and DIN1 Held High
Stop
Bit
Start
Bit
DIN0
Stop
Bit
Start
Bit
Stop
Bit
Start
Bit
Stop
Bit
Start
Bit
DIN1
DIN4 Held Low and DIN5 Held High
Stop
Bit
Start
Bit
DIN4
DIN5
DIN8 Held Low and DIN9 Held High
Stop
Bit
Start
Bit
DIN8
DIN9
Figure 2. RMT Pattern Examples
DATA TRANSMISSION MODE
After initialization and synchronization, the serializer accepts parallel data from inputs DIN0–DIN9. The serializer
uses the TCLK input to latch the incoming data. The TCLK_R/F pin selects which edge the serializer uses to
strobe incoming data. If either of the SYNC inputs is high for six TCLK cycles, the data at DIN0–DIN9 is ignored
regardless of the clock edge selected and 1026 cycles of SYNC pattern are sent.
After determining which clock edge to use, a start and stop bit, appended internally, frames the data bits in the
register. The start bit is always high and the stop bit is always low. The start and stop bits function as the
embedded clock bits in the serial stream.
The serializer transmits serialized data and appended clock bits (10+2 bits) from the serial data output (DO±) at
12 times the TCLK frequency. For example, if TCLK is 66 MHz, the serial rate is 66 × 12 = 792 Mbps. Because
only 10 bits are input data, the useful data rate is 10 times the TCLK frequency. For instance, if TCLK = 66 MHz,
the useful data rate is 66 × 10 = 660 Mbps. The data source, which provides TCLK, must be in the range of
10 MHz to 66 MHz.
The serializer outputs (DO±) can drive point-to-point connections or limited multipoint or multidrop backplanes.
The outputs transmit data when the enable pin (DEN) is high, PWRDN = high, and SYNC1 and SYNC2 are low.
When DEN is driven low, the serializer output pins enter the high-impedance state.
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SN65LV1224B-EP
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SGLS358 – SEPTEMBER 2006
FUNCTIONAL DESCRIPTION (continued)
Once the deserializer has synchronized to the serializer, the LOCK pin transitions low. The deserializer locks to
the embedded clock and uses it to recover the serialized data. ROUT data is valid when LOCK is low, otherwise
ROUT0–ROUT9 is invalid. The ROUT0–ROUT9 data is strobed out by RCLK. The specific RCLK edge polarity to be
used is selected by the RCLK_R/F input. The ROUT0–ROUT9, LOCK and RCLK outputs can drive a maximum of
three CMOS input gates (15-pF load total for all three) with a 66-MHz clock.
POWER DOWN
When no data transfer is required, the power-down mode can be used. The serializer and deserializer use the
power-down state, a low-power sleep mode, to reduce power consumption. The deserializer enters power down
when you drive PWRDN and REN low. The serializer enters power down when you drive PWRDN low. In power
down, the PLL stops and the outputs enter a high-impedance state, which disables load current and reduces
supply current to the milliampere range. To exit power down, you must drive the PWRDN pin high.
Before valid data exchanges between the serializer and deserializer can resume, you must reinitialize and
resynchronize the devices to each other. Initialization of the serializer takes 1026 TCLK cycles. The deserializer
initialize and drives LOCK high until lock to the LVDS clock occurs.
HIGH-IMPEDANCE MODE
The serializer enters the high-impedance mode when the DEN pin is driven low. This puts both driver output
pins (DO+ and DO–) into a high-impedance state. When you drive DEN high, the serializer returns to the
previous state, as long as all other control pins remain static (SYNC1, SYNC2, PWRDN, TCLK_R/F). When the
REN pin is driven low, the deserializer enters high-impedance mode. Consequently, the receiver output pins
ROUT0–ROUT9) and RCLK are placed into the high-impedance state. The LOCK output remains active, reflecting
the state of the PLL.
Deserializer Truth Table
INPUTS
(1)
(2)
(3)
OUTPUTS
PWRDN
REN
ROUT(0:9) (1)
H
H
Z
H
H
L
X
H
L
LOCK
(2)
RCLK (1) (3)
H
Z
Active
L
Active
Z
Z
Z
Z
Active
Z
ROUT and RCLK are 3-stated when LOCK is asserted high.
LOCK output reflects the state of the deserializer with regard to the selected data stream.
RCLK active indicates the RCLK is running if the deserializer is locked. The timing of RCLK with respect to ROUT is determined by
RCLK_R/F.
FAILSAFE BIASING FOR THE SN65LV1224B
The SN65LV1224B has an input threshold sensitivity of ±50 mV. This allows for greater differential noise margin
in the SN65LV1224B. However, in cases where the receiver input is not being actively driven, the increased
sensitivity of the SN65LV1224B can pickup noise as a signal and cause unintentional locking. This may occur
when the input cable is disconnected. The SN65LV1224B has an on-chip fail-safe circuit that drives the serial
input and LOCK signal high. The response time of the fail-safe circuit depends on interconnect characteristics.
6
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TERMINAL FUNCTIONS
PIN
DB PACKAGE
I/O
DESCRIPTION
SERIALIZER
18, 20, 23, 25
AGND
Analog circuit ground (PLL and analog circuits)
17, 26
AVCC
Analog circuit power supply (PLL and analog circuits)
19
DEN
LVTTL logic input. Low puts the LVDS serial output into the high-impedance state.
High enables serial data output.
15, 16
DGND
3–12
DIN0 – DIN9
21
DO–
Inverting LVDS differential output
22
DO+
Noninverting LVDS differential output
27, 28
DVCC
Digital circuit power supply
24
PWRDN
LVTTL logic input. Asserting this pin low turns off the PLL and places the outputs
into the high-impedance state, putting the device into a low-power mode.
1, 2
SYNC1,
SYNC2
LVTTL logic inputs SYNC1 and SYNC2 are ORed together. When at least one of
the two pins is asserted high for 6 cycles of TCLK, the serializer initiates
transmission of a minimum 1026 SYNC patterns. If after completion of the
transmission of 1026 patterns SYNC continues to be asserted, then the
transmission continues until SYNC is driven low and if the time SYNC holds > 6
cycles, another 1026 SYNC pattern transmission initiates.
13
TCLK_R/F
14
TCLK
LVTTL-level reference clock input. The SN65LV1023A accepts a 10-MHz to
66-MHz clock. TCLK strobes parallel data into the input latch and provides a
reference frequency to the PLL.
1, 12, 13
AGND
Analog circuit ground (PLL and analog circuits)
4, 11
AVCC
Analog circuit power supply (PLL and analog circuits)
14, 20, 22
DGND
Digital circuit ground
21, 23
DVCC
Digital circuit power supply
10
LOCK
LVTTL level output. LOCK goes low when the deserializer PLL locks onto the
embedded clock edge.
Digital circuit ground
Parallel LVTTL data inputs
LVTTL logic input. Low selects a TCLK falling-edge data strobe; high selects a
TCLK rising-edge data strobe.
DESERIALIZER
LVTTL logic input. Asserting this pin low turns off the PLL and places outputs into a
high-impedance state, putting the device into a low-power mode. To initiate power
down, this pin is held low for a minimum of 16 ns. As long as PWRDN is held low,
the device is in the power down state.
7
PWRDN
2
RCLK_R/F
9
RCLK
3
REFCLK
LVTTL logic input. Use this pin to supply a REFCLK signal for the internal PLL
frequency.
8
REN
LVTTL logic input. Low places ROUT0–ROUT9 and RCLK in the high-impedance
state.
5
RI+
Serial data input. Noninverting LVDS differential input
6
RI–
Serial data input. Inverting LVDS differential input
28–24, 19–15
ROUT0–ROUT9
LVTTL logic input. Low selects an RCLK falling-edge data strobe; high selects an
RCLK rising-edge data strobe.
LVTTL level output recovered clock. Use RCLK to strobe ROUTx.
Parallel LVTTL data outputs
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SN65LV1224B-EP
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SGLS358 – SEPTEMBER 2006
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted) (1)
UNIT
VCC to GND
–0.3 V to 4 V
LVTTL input voltage
–0.3 V to (VCC + 0.3 V)
LVTTL output voltage
–0.3 V to (VCC + 0.3 V)
LVDS receiver input voltage
–0.3 V to 3.9 V
LVDS driver output voltage
–0.3 V to 3.9 V
LVDS output short circuit duration
Electrostatic discharge:
10 ms
HBM
up to 6 kV
MM
up to 200 V
Junction temperature
150°C
Storage temperature (2)
–65°C to 150°C
Lead temperature (soldering, 4 seconds)
260°C
DB package maximum package
power dissipation
1.27 W
TA = 25°C
DB package derating
(1)
(2)
10.8 mW/°C above 25°C
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Long term high temperature storage and/or extended use at maximum operating conditions may result in a reduction of overall device
life. See http://www.ti.com/ep_quality for additional information on enhanced plastic packaging.
RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
VCC (1)
MIN
NOM
MAX
3
3.3
3.6
V
0
2.4
V
ID
2
ǒ Ǔ
V
Supply voltage
Receiver input voltage range
VCM
Receiver input common mode range
V
V
2.4 *
Supply noise voltage
TA
(1)
8
Operating free-air temperature
–55
25
ID
2
UNIT
100
mVp-p
125
°C
By design, DVCC and AVCC are separated internally and does not matter what the difference is for |DVCC–AVCC|, as long as both are
within 3 V to 3.6 V.
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ELECTRICAL CHARACTERISTICS
over recommended operating supply and temperature ranges (unless otherwise specified)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VCC
V
0.8
V
SERIALIZER LVCMOS/LVTTL DC SPECIFICATIONS (1)
VIH
High-level input voltage
VIL
Low-level input voltage
VCL
Input clamp voltage
IIN
Input current,
(2)
2
GND
ICL = –18 mA
VIN = 0 V or 3.6 V
–200
-0.86
–1.5
V
±100
200
µA
DESERIALIZER LVCMOS/LVTTL DC SPECIFICATIONS (3)
VIH
High-level input voltage
2
VCC
V
VIL
Low-level input voltage
GND
0.8
V
VCL
Input clamp voltage
ICL = –18 mA
IIN
Input current (pull-up and
pull-down resistors on inputs)
VIN = 0 V or 3.6 V
VOH
High-level output voltage
IOH = –5 mA
VOL
Low-level output voltage
IOL = 5 mA
IOS
Output short-circuit current
VOUT = 0 V
IOZ
High-impedance output current
PWRDN or REN = 0.8 V, VOUT = 0 V or VCC
–0.62
–200
–1.5
V
200
µA
VCC
V
2.2
3
GND
0.25
0.5
V
–47
–85
mA
–10
±1
10
µA
350
450
SERIALIZER LVDS DC SPECIFICATIONS (Apply to Pins DO+ and DO–)
RL = 27 Ω, See Figure 20
VOD
Output differential voltage
(DO+)–(DO–)
∆VOD
Output differential voltage
unbalance
VOS
Offset voltage
∆VOS
Offset voltage unbalance
IOS
Output short circuit current
D0 = 0 V, DINx = high,
PWRDN and DEN = 2.4 V
IOZ
High-impedance output current
PWRDN or DEN = 0.8 V,
DO = 0 V or VCC
IOX
Power-off output current
VCC = 0 V, DO = 0 V or 3.6 V
CO
Output single-ended capacitance
mV
35
1.1
mV
1.2
1.3
V
4.8
35
mV
–10
–90
mA
–10
±1
10
µA
–20
±1
25
µA
1
pF
DESERIALIZER LVDS DC SPECIFICATIONS (Apply to Pins RI+ and RI–)
VTH
Differential threshold high voltage
VTL
Differential threshold low voltage
IIN
Input current
CI
Input single-ended capacitance
VCM = 1.1 V
50
–50
mV
mV
VIN = 2.4 V, VCC = 3.6 V or 0 V
–10
±1
15
VIN = 0 V, VCC = 3.6 V or 0 V
–10
±0.05
10
0.5
µA
pF
SERIALIZER SUPPLY CURRENT (Applies to Pins DVCC and AVCC)
ICCD
Serializer supply current worst
case
RL = 27 Ω, See Figure 5
ICCXD
Serializer supply current
PWRDN = 0.8 V
f = 10 MHz
20
25
f = 66 MHz
55
70
200
500
f = 10 MHz
15
35
f = 66 MHz
80
95
0.36
1
mA
µA
DESERIALIZER SUPPLY CURRENT (applies to pins DVCC and AVCC)
ICCR
Deserializer supply current, worst
case
ICCXR
Deserializer supply current, power
down
(1)
(2)
(3)
CL = 15 pF, See Figure 5
PWRDN = 0.8 V, REN = 0.8 V
mA
mA
Apply to DIN0–DIN9, TCLK, PWRDN, TCLK_R/F, SYNC1, SYNC2, and DEN
High IIN values are due to pullup and pulldown resistors on the inputs.
Apply to pins PWRDN, RCLK_R/F, REN, and REFCLK = inputs; apply to pins ROUTx, RCLK, and LOCK = outputs (see Deserializer truth
table)
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SERIALIZER TIMING REQUIREMENTS FOR TCLK
over recommended operating supply and temperature ranges (unless otherwise specified)
PARAMETER
MIN
TYP
MAX
UNIT
15.15
T
100
ns
Transmit clock high time
0.4T
0.5T
0.6T
ns
tTCIL
Transmit clock low time
0.4T
0.5T
0.6T
ns
tt(CLK)
TCLK input transition time
3
6
tJIT
TCLK input jitter
tTCP
Transmit clock period
tTCIH
TEST CONDITIONS
See Figure 19
Frequency tolerance
–100
ns
150
ps (RMS)
+100
ppm
MAX
UNIT
SERIALIZER SWITCHING CHARACTERISTICS
over recommended operating supply and temperature ranges (unless otherwise specified)
PARAMETER
TEST CONDITIONS
MIN
RL = 27 Ω, CL = 10 pF to GND, See
Figure 6
TYP
tTLH(L)
LVDS low-to-high transition time
tLTHL(L)
LVDS high-to-low transition time
tsu(DI)
DIN0–DIN9 setup to TCLK
tsu(DI)
DIN0–DIN9 hold from TCLK
td(HZ)
DO± high-to-high impedance state
delay
td(LZ)
DO± low-to-high impedance state
delay
td(ZH)
DO± high-to-high impedance
state-to-high delay
5
td(ZL)
DO± high-to-high impedance
state-to-low delay
6.5
tw(SPW)
SYNC pulse duration
t(PLD)
Serializer PLL lock time
td(S)
Serializer delay
RL = 27 Ω, See Figure 13
tDJIT
Deterministic jitter
RL = 27 Ω, CL = 10 pF to GND
RL = 27 Ω, CL = 10 pF to GND, See
Figure 9
0.2
ns
0.25
ns
0.5
ns
4
RL = 27 Ω, CL = 10 pF to GND, See
Figure 10
ns
2.5
2.5
RL = 27 Ω, See Figure 12
ns
6×tTCP
ns
1026×tTCP
tTCP
ns
tTCP+2
tTCP+3
230
ps
150
tRJIT
Random jitter
RL = 2.7 Ω, CL = 10 pF to GND
ns
10
ps (RMS)
DESERIALIZER TIMING REQUIREMENTS FOR REFCLK
over recommended operating supply and temperature ranges (unless otherwise specified)
PARAMETER
tRFCP
REFCLK period
tRFDC
REFCLK duty cycle
tt(RF)
REFCLK transition time
TEST CONDITIONS
TYP
MAX
UNIT
T
100
ns
30%
50%
70%
3
Frequency tolerance
10
MIN
15.15
–100
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+100
ns
ppm
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DESERIALIZER SWITCHING CHARACTERISTICS
over recommended operating supply and temperature ranges (unless otherwise specified)
PARAMETER
t(RCP)
Receiver out clock period
tTLH(C))
CMOS/TTL low-to-high
transition time
tTHL(C))
CMOS/TTL high-to-low
transition time
td(D) (1)
Deserializer delay, See
Figure 14
t(ROS)
TEST
CONDITIONS
t(RCP) = t(TCP), See
Figure 13
CL = 15 pF, CL =
15 pF, See
Figure 7
PIN/FREQ
RCLK
MIN
TYP
15.15
ROUT0–ROUT9
,
LOCK, RCLK
MAX
UNIT
100
ns
1.2
ns
1.1
Room temperature, 10 MHz
3.3 V
1.75×t(RCP)
+4.2
1.75×t(RCP)
+12.6
66 MHz
1.75×t(RCP)
+7.4
1.75×t(RCP)
+9.7
ROUTx data valid before RCLK
See Figure 15
RCLK 10 MHz
0.4×t(RCP)
0.5×t(RCP)
RCLK 66 MHz
0.4×t(RCP)
0.5×t(RCP)
10 MHz
–0.4×t(RCP)
–0.5×t(RCP)
66 MHz
–0.4×t(RCP)
–0.5×t(RCP)
40%
50%
ns
ns
ns
t(ROH)
ROUTx data valid after RCLK
t(RDC)
RCLK duty cycle
td(HZ)
High-to-high impedance state
delay
6.5
ns
td(LZ)
Low-to-high impedance state
delay
4.7
ns
td(HR)
High-impedance state to high
delay
5.3
ns
td(ZL)
High-impedance state to low
delay
4.7
ns
t(DSR1)
Deserializer PLL lock time from
PWRDN (with SYNCPAT)
t(DSR2)
Deserializer PLL lock time from
SYNCPAT
td(ZHLK)
High-impedance state to high
delay (power up)
tRNM
Deserializer noise margin
(1)
(2)
(3)
See Figure 16
See Figure 17,
Figure 18,
and (2)
ROUT0–ROUT9
10 MHz
850 × tRFCP
66 MHz
850 × tRFCP
10 MHz
2
66 MHz
0.303
LOCK
See Figure 19 and
(3)
60%
3
10 MHz
3680
66 MHz
540
ns
µs
ns
ps
The deserializer delay time for all frequencies does not exceed two serial bit times.
t(DSR1) represents the time required for the deserializer to register that a lock has occurred upon powerup or when leaving the
powerdown mode. t(DSR2) represents the time required to register that a lock has occurred for the powered up and enabled deserializer
when the input (RI±) conditions change from not receiving data to receiving synchronization patterns (SYNCPATs). In order to specify
deserializer PLL performance, tDSR1 and tDSR2 are specified with REFCLK active and stable and specific conditions of SYNCPATs.
tRNM represents the phase noise or jitter that the deserializer can withstand in the incoming data stream before bit errors occur.
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TIMING DIAGRAMS AND TEST CIRCUITS
TCLK
ODD DIN
EVEN DIN
Figure 3. Worst-Case Serializer ICC Test Pattern
SUPPLY CURRENT
vs
TCLK FREQUENCY
60
66 mA, 48.880 MHz
ICC − Supply Current − mA
50
40
ICC
30
20
10 mA, 14.732 MHz
10
0
0
20
40
TCLK Frequency − MHz
Figure 4.
12
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60
80
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SGLS358 – SEPTEMBER 2006
TIMING DIAGRAMS AND TEST CIRCUITS (continued)
RCLK
ODD ROUT
EVEN ROUT
Figure 5. Worst-Case Deserializer ICC Test Pattern
10 pF
tTLH(L)
DO+
tTHL(L)
RL
80%
Vdiff
80%
20%
20%
DO−
10 pF
Vdiff = (DO+) − (DO−)
Figure 6. Serializer LVDS Output Load and Transition Times
CMOS/TTL Output
Deserializer
tTHL(C)
tTLH(C)
80%
15 pF
80%
20%
20%
Figure 7. Deserializer CMOS/TTL Output Load and Transition Times
tt(CLK)
TCLK
tt(CLK)
90%
10%
90%
10%
3V
0V
Figure 8. Serializer Input Clock Transition Time
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TIMING DIAGRAMS AND TEST CIRCUITS (continued)
tTCP
1.5 V
TCLK
1.5 V
For TCLK_R/F = Low
1.5 V
th(DI)
tsu(DI)
DIN [9:0]
1.5 V
Setup
Hold
1.5 V
Figure 9. Serializer Setup/Hold Times
Parasitic Package and
Trace Capacitance
3V
DEN
1.5 V
1.5 V
0V
td(ZH)
td(HZ)
VOH
13.5 Ω
DO+
50%
1.1 V
DO−
DO±
50%
1.1 V
td(ZL)
td(LZ)
13.5 Ω
DEN
1.1 V
50%
50%
VOL
Figure 10. Serializer High-Impedance State Test Circuit and Timing
PWRDN
2V
0.8 V
1026 Cycles
td(HZ) or td(LZ)
TCLK
td(ZH) or td(ZL)
tPLD
DO±
3-State
Output Active
Figure 11. Serializer PLL Lock Time and PWRDN High-Impedance State Delays
14
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TIMING DIAGRAMS AND TEST CIRCUITS (continued)
REN
PWRDN
TCLK
tw(SP)
SYNC1
or
SYNC2
DO±
DATA
SYNC Pattern
TCLK
SYNC1
or
SYNC2
tw(SP) Min. Timing Met
DO±
SYNC Pattern
DATA
Figure 12. SYNC Timing Delays
DIN
DIN0 − DIN9 SYMBOL N
DIN0 − DIN9 SYMBOL N+1
td(S)
TCLK
Timing for TCLK_R/F = High
Start
D00 − D09 SYMBOL N−1
Bit
Stop Start
Bit Bit
D00 − D09 SYMBOL N
Stop
Bit
DO
Figure 13. Serializer Delay
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TIMING DIAGRAMS AND TEST CIRCUITS (continued)
Start
Bit
D00 − D09 SYMBOL N
Stop Start
Bit Bit
D00 − D09 SYMBOL N+1
Stop Start
Bit Bit
D00 − D09 SYMBOL N+2
Stop
Bit
RI
1.2 V
1V
tDD
RCLK
Timing for TCLK_R/F = High
ROUT
ROUT0 − ROUT9 SYMBOL N−1
ROUT0 − ROUT9 SYMBOL N+1
ROUT0 − ROUT9 SYMBOL N
Figure 14. Deserializer Delay
tLow
tHigh
RCLK
RCLK_R/F = Low
tHigh
tLow
RCLK
RCLK_R/F = High
tROH
tROS
ROUT [9:0]
1.5 V
Data Valid
Before RCLK
Data Valid
After RCLK
1.5 V
Figure 15. Deserializer Data Valid Out Times
7 V x (LZ/ZL), Open (HZ/ZH)
VOH
REN
500 Ω
450 Ω
1.5 V
1.5 V
VOL
Scope
td(LZ)
VOL + 0.5 V
50 Ω
td(ZL)
VOL + 0.5 V
VOL
ROUT[9:0]
td(HZ)
td(ZH)
VOH
VOH − 0.5 V
Figure 16. Deserializer High-Impedance State Test Circuit and Timing
16
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VOH − 0.5 V
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SN65LV1224B-EP
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SGLS358 – SEPTEMBER 2006
TIMING DIAGRAMS AND TEST CIRCUITS (continued)
PWRDN
2V
0.8 V
REFCLK
1.5 V
t(DSR1)
DATA
RI±
Not Important
td(ZHL)
LOCK
SYNC Patterns
3-State
3-State
td(HZ) or td(LZ)
td(ZH) or td(ZL)
ROUT[9:0]
3-State
3-State
SYNC Symbol or DIN[9:0]
RCLK
3-State
3-State
RCLK_R/F = Low
REN
Figure 17. Deserializer PLL Lock Times and PWRDN 3-State Delays
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TIMING DIAGRAMS AND TEST CIRCUITS (continued)
3.6 V
3V
VCC
0V
PWRDN
0.8 V
REFCLK
t(DSR2)
DATA
1.2 V
RI±
Not Important
1V
SYNC Patterns
LOCK
3-State
td(ZH) or td(ZL)
ROUT[9:0]
td(HZ) or td(LZ)
3-State
3-State
SYNC Symbol or DIN[9:0]
RCLK
3-State
3-State
REN
Figure 18. Deserializer PLL Lock Time From SyncPAT
1.2 V
VTH
RI±
VTL
1V
tDJIT
tDJIT
tRNM
tRNM
tSW
Ideal Sampling Position
tSW: Setup and Hold Time (Internal Data Sampling Window)
tDJIT: Serializer Output Bit Position Jitter That Results From Jitter on TCLK
tRNM: Receiver Noise Margin Time
Figure 19. Receiver LVDS Input Skew Margin
18
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TIMING DIAGRAMS AND TEST CIRCUITS (continued)
DO+
RL
10
DIN
Parallel-to-Serial
DO−
> TCLK
VOD = (DO+) − (DO−)
Differential Output Signal Is Shown as (DO+) − (DO−)
Figure 20. VOD Diagram
DEVICE STARTUP PROCEDURE
It is recommended that the PWRDNB pin on both the SN65LV1023A and the SN65LV1224B device be held to a
logic LOW level until after the power supplies have powered up to at least 3 V as shown in Figure 21.
3.0 V
VDD
PWRDNB
Figure 21. Device Startup
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APPLICATION INFORMATION
DIFFERENTIAL TRACES AND TERMINATION
The performance of the SN65LV1023A/SN65LV1224B is affected by the characteristics of the transmission
medium. Use controlled-impedance media and termination at the receiving end of the transmission line with the
media’s characteristics impedance.
Use balanced cables such as twisted pair or differential traces that are ran close together. A balanced cable
picks up noise together and appears to the receiver as common mode. Differential receivers reject
common-mode noise. Keep cables or traces matched in length to help reduce skew.
Running the differential traces close together helps cancel the external magnetic field, as well as maintain a
constant impedance. Avoiding sharp turns and reducing the number of vias also helps.
TOPOLOGIES
There are several topologies that the serializers can operate. Three common examples are shown below.
Figure 22 shows an example of a single-terminated point-to-point connection. Here a single termination resistor
is located at the deserializer end. The resistor value should match that of the characteristic impedance of the
cable or PC board traces. The total load seen by the serializer is 100 Ω. Double termination can be used and
typically reduces reflections compared with single termination. However, it also reduces the differential output
voltage swing.
AC-coupling is only recommended if the parallel TX data stream is encoded to achieve a dc-balanced data
stream. Otherwise the ac-capacitors can induce common mode voltage drift due to the dc-unbalanced data
stream.
Serialized Data
100 Ω
Parallel Data In
Parallel Data Out
Figure 22. Single-Terminated Point-to-Point Connection
Figure 23 shows an example of a multidrop configuration. Here there is one transmitter broadcasting data to
multiple receivers. A 50-kΩ resistor at the far end terminates the bus.
ASIC
ASIC
ASIC
ASIC
50 Ω
Figure 23. Multidrop Configuration
Figure 24 shows an example of multiple serializers and deserializers on the same differential bus, such as in a
backplane. This is a multipoint configuration. In this situation, the characteristic impedance of the bus can be
significantly less due to loading. Termination resistors that match the loaded characteristic impedance are
required at each end of the bus. The total load seen by the serializer in this example is 27 Ω.
20
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SGLS358 – SEPTEMBER 2006
APPLICATION INFORMATION (continued)
ASIC
ASIC
ASIC
54 Ω
ASIC
54 Ω
Figure 24. Multiple Serializers and Deserializers on the Same Differential Bus
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21
PACKAGE MATERIALS INFORMATION
www.ti.com
14-Jul-2012
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
SN65LV1023AMDBREP
SSOP
DB
28
2000
330.0
16.4
8.1
10.4
2.5
12.0
16.0
Q1
SN65LV1224BMDBREP
SSOP
DB
28
2000
330.0
16.4
8.1
10.4
2.5
12.0
16.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
14-Jul-2012
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
SN65LV1023AMDBREP
SSOP
DB
28
2000
367.0
367.0
38.0
SN65LV1224BMDBREP
SSOP
DB
28
2000
367.0
367.0
38.0
Pack Materials-Page 2
MECHANICAL DATA
MSSO002E – JANUARY 1995 – REVISED DECEMBER 2001
DB (R-PDSO-G**)
PLASTIC SMALL-OUTLINE
28 PINS SHOWN
0,38
0,22
0,65
28
0,15 M
15
0,25
0,09
8,20
7,40
5,60
5,00
Gage Plane
1
14
0,25
A
0°–ā8°
0,95
0,55
Seating Plane
2,00 MAX
0,10
0,05 MIN
PINS **
14
16
20
24
28
30
38
A MAX
6,50
6,50
7,50
8,50
10,50
10,50
12,90
A MIN
5,90
5,90
6,90
7,90
9,90
9,90
12,30
DIM
4040065 /E 12/01
NOTES: A.
B.
C.
D.
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Body dimensions do not include mold flash or protrusion not to exceed 0,15.
Falls within JEDEC MO-150
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