MAX9268GCM/V+ Maxim Integrated Products, MAX9268GCM/V+ Datasheet - Page 28

MAX9268GCM/V+

Manufacturer Part Number

MAX9268GCM/V+

Description

IC SERIALIZER GMSL LVDS 48TQFP

Manufacturer

Maxim Integrated Products

Datasheets

1.MAX9268GCMV.pdf (35 pages)

2.MAX9268GCMV.pdf (35 pages)

Specifications of MAX9268GCM/V+

Function

Deserializer

Data Rate

2.5Gbs

Input Type

Serial

Output Type

LVDS

Voltage - Supply

3.3V

Operating Temperature

-40°C ~ 105°C

Mounting Type

Surface Mount

Package / Case

48-TQFN Exposed Pad

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Number Of Outputs

Number Of Inputs

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Gigabit Multimedia Serial Link Deserializer

with LVDS System Interface

Both the GMSL serializer and the MAX9268 have program-

mable device addresses. This allows multiple GMSL devic-

es along with I

channel. The serializer device address is stored in registers

0x00 of each device, while the deserializer device address

is stored in register 0x01 of each device. To change the

device address, first write to the device whose address

changes (register 0x00 of the GMSL serializer for serializer

device address change, or register 0x01 of the MAX9268

for deserializer device address change). Then write the

same address into the corresponding register on the other

device (register 0x00 of the MAX9268 for serializer device

address change, or register 0x01 of the GMSL serializer for

deserializer device address change).

ADD0 and ADD1 are 3-level inputs, which set the device

addresses stored in the MAX9268 (Table 2). Set the

desired device addresses by connecting ADD0/ADD1

through a pullup resistor to IOVDD, a pulldown resistor to

GND, or to high impedance. For digital control, use three-

state logic to drive the 3-level logic inputs.

ADD0/ADD1 set the device addresses in the MAX9268

only and not the GMSL serializer. Set the GMSL serial-

izer’s ADD0/ADD1 inputs to the same settings as the

MAX9268; alternatively, write to registers 0x00 and 0x01

of the GMSL serializer to reflect any changes made due

to the 3-level inputs.

Both I

provide a logic-high level. There are trade-offs between

power dissipation and speed, and a compromise made in

choosing pullup resistor values. Every device connected

to the bus introduces some capacitance even when the

device is not in operation. I

go from low to high (30% to 70%) for fast mode, which is

defined for data rates up to 400kbps (see the I

tions in the AC Electrical Characteristics section for details).

To meet the fast-mode rise-time requirement, choose the

pullup resistors such that rise time t

transition time becomes too slow. The MAX9268 supports

BUS

C/UART rates up to 1Mbps.

_____________________________________________________________________________________

3-Level Inputs for Default Device Address

< 300ns. The waveforms are not recognized if the

C/UART open-drain lines require pullup resistors to

Choosing I

Programming the Device Addresses

C peripherals to coexist on the same control

C/UART Pullup Resistors

C specifies 300ns rise times to

= 0.85 x R

C specifica-

PULLUP

AC-coupling isolates the receiver from DC voltages up

to the voltage rating of the capacitor. Four capacitors

(two at the serializer output and two at the deserializer

input) are needed for proper link operation and to provide

protection if either end of the cable is shorted to a high volt-

age. AC-coupling blocks low-frequency ground shifts and

low-frequency common-mode noise.

Voltage droop and the digital sum variation (DSV) of

transmitted symbols cause signal transitions to start from

different voltage levels. Because the transition time is finite,

starting the signal transition from different voltage levels

causes timing jitter. The time constant for an AC-coupled

link needs to be chosen to reduce droop and jitter to an

acceptable level. The RC network for an AC-coupled link

consists of the CML receiver termination resistor (R

the CML driver termination resistor (R

AC-coupling capacitors (C). The RC time constant for four

equal-value series capacitors is (C x (R

and R

ance (usually 100I). This leaves the capacitor selection

to change the system time constant. Use at least 0.2FF

high-frequency surface-mount ceramic capacitors, with

sufficient voltage rating to withstand a short to battery, to

pass the lower speed reverse control-channel signal. Use

capacitors with a case size less than 3.2mm x 1.6mm to

have lower parasitic effects to the high-speed signal.

The MAX9268 uses a 3.0V to 3.6V V

single-ended inputs and outputs on the MAX9268 derive

power from a 1.7V to 3.6V V

IOVDD. Proper voltage-supply bypassing is essential for

high-frequency circuit stability.

Interconnect for CML typically has a differential impedance

of 100I. Use cables and connectors that have matched

differential impedance to minimize any impedance dis-

continuities. Twisted-pair and shielded twisted-pair cables

tend to generate less EMI due to magnetic-field canceling

effects. Balanced cables pick up noise as common mode

rejected by the CML receiver. Table 11 lists the suggested

cables and connectors used in the GMSL link.

are required to match the transmission line imped-

Power-Supply Circuits and Bypassing

Selection of AC-Coupling Capacitors

Cables and Connectors

IOVDD

AVDD

, which scales with

), and the series

AC-Coupling

and V

+ R

DVDD

))/4. R

. All

MAX9268GCM/V+ Maxim Integrated Products, MAX9268GCM/V+ Datasheet - Page 28

MAX9268GCM/V+

Specifications of MAX9268GCM/V+

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