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S2204
QUAD GIGABIT ETHERNET DEVICE
July 16, 1999 / Revision C
S2204
QUAD GIGABIT ETHERNET DEVICE
DEVICE
SPECIFICATION
MAC
(ASIC)
S2004
QUAD
GIGABIT
ETHERNET
INTERFACE
MAC
(ASIC)
MAC
(ASIC)
MAC
(ASIC)
TO SERIAL BACKPLANE
S2204
GE INTERFACE
SERIAL BP DRIVER
Figure 1. Typical Quad Gigabit Ethernet Application
FEATURES
1250 MHz (Gigabit Ethernet) operating rate
- 1/2 Rate Operation
Quad Transmitter with phase-locked loop (PLL)
clock synthesis from low speed reference
Quad Receiver PLL provides clock and data
recovery
Internally series terminated TTL outputs
Low-jitter serial PECL interface
Individual local loopback control
JTAG 1149.1 Boundary scan on low speed I/O
signals
Interfaces with coax, twinax, or fiber optics
Single +3.3V supply, 2.5 W power dissipation
Compact 23mm x 23mm 208 TBGA package
APPLICATIONS
Ethernet Backbones
Workstation
Frame buffer
Switched networks
Data broadcast environments
Proprietary extended backplanes
GENERAL DESCRIPTION
The S2204 facilitates high-speed serial transmission
of data in a variety of applications including Gigabit
Ethernet, serial backplanes, and proprietary point to
point links. The chip provides four separate trans-
ceivers which can be operated individually for a data
capacity of >4 Gbps.
Each bi-directional channel provides parallel to serial
and serial to parallel conversion, clock generation/
recovery, and framing. The on-chip transmit PLL
synthesizes the high-speed clock from a low-speed
reference. The on-chip quad receive PLL is used for
clock recovery and data re-timing on the four inde-
pendent data inputs. The transmitter and receiver
each support differential PECL-compatible I/O for
copper or fiber optic component interfaces with ex-
cellent signal integrity. Local loopback mode allows
for system diagnostics. The chip requires a 3.3V
power supply and dissipates 2.5 watts.
Figure 1 shows the S2204 and S2004 in a Gigabit
Ethernet application. Figure 2 combines the
S2204 with a crosspoint switch to demonstrate a
serial backplane application. Figure 3 is the input/
output diagram. Figures 4 and 5 show the transmit
and receive block diagrams, respectively.