SI5100-F-BC Silicon Laboratories Inc, SI5100-F-BC Datasheet - Page 21

SI5100-F-BC

Manufacturer Part Number

SI5100-F-BC

Description

IC TXRX SERIAL/DESERIAL 195CBGA

Manufacturer

Silicon Laboratories Inc

Type

Transceiverr

Series

SiPHY®r

Datasheets

1.SI5100-F-BC.pdf (40 pages)

2.SI5100-H-BL.pdf (40 pages)

Specifications of SI5100-F-BC

Package / Case

196-BGA

Number Of Drivers/receivers

1/1

Protocol

SONET/SDH

Voltage - Supply

1.71 V ~ 1.89 V

Mounting Type

Surface Mount

Product

RF / Wireless

Supply Voltage (max)

1.89 V, 3.47 V

Supply Voltage (min)

1.71 V

Supply Current

0.83 A

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 20 C

Mounting Style

SMD/SMT

Maximum Power Dissipation

1600 mW

Number Of Channels

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Contains lead / RoHS non-compliant

Other names

336-1135
SI5100-BC

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Part Number:

SI5100-F-BC

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9. Line Loopback

The Si5100 provides a line loopback mode that

establishes a loopback path from the high-speed

receive input to the high-speed transmit output. This

provides a mechanism for looping back the high-speed

clock and data recovered from RXDIN to the transmit

data output, TXDOUT, and clock, TXCLKOUT. This

mode is enabled when the LLBK input is set low.

Note: Setting both DLBK and LLBK low simultaneously is not

10. Bias Generation Circuitry

The Si5100 uses two external resistors, RXREXT and

TXREXT, to set internal bias currents for the receive

and transmit sections of the device, respectively. The

external resistors allow precise generation of bias

currents,

consumption. The bias generation circuitry requires two

3.09 k Ω (1%) resistors each connected between

RXREXT and GND and between TXREXT and GND.

11. Reference Clock

The Si5100 supports operation with one of two possible

reference clock sources. In the first configuration, an

external reference clock is connected to the REFCLK

input. The second configuration uses the parallel data

clock, TXCLK16IN, as the reference clock source. The

REFSEL input is used to select whether the REFCLK or

the TXCLK16IN input are used as the reference clock.

When REFCLK is selected as the reference clock

source (REFSEL = 1), two possible reference clock

frequencies are supported. The reference clock

frequency provided on the REFCLK input can be either

1/16th or 1/32th the desired transceiver data rate. The

REFCLK frequency is selected using the REFRATE

input.

The TXCLK16IN clock frequency is equal to either 1/4th

or 1/16th the transceiver data rate depending on the

state of the MODE16 input. When TXCLK16IN is

selected as the reference clock source (REFSEL = 0),

the REFRATE input has no effect.

The CMU in the Si5100’s transmit section multiplies the

provided reference up to the serial transmit data rate.

When the CMU has achieved lock with the selected

reference, the TXLOL output is deasserted (driven

high).

The CDR in the receive section of the Si5100 uses the

selected reference clock to center the receiver PLL

frequency in order to speed lock acquisition. When the

receive CDR locks to the data input, the RXLOL signal

is deasserted (driven high).

supported.

which

can

significantly

reduce

power

Rev. 1.1

12. Reset

The Si5100 is reset by holding the RESET pin low for at

least 1 µ s. When RESET is asserted, the input FIFO

pointers are reset and the digital control circuitry is

initialized.

When RESET transitions high to start normal operation,

the transmit CMU calibration is performed.

13. Transmit Differential Output

Circuitry

The Si5100 utilizes a current-mode logic (CML)

architecture to drive the high-speed serial output clock

and data on TXCLKOUT and TXDOUT. An example of

output termination with ac coupling is shown in Figure 9.

In applications with direct dc coupling, the 0.1 µ F

capacitors can be omitted. The differential peak-to-peak

voltage swing of the CML architecture is listed in

Table 2.

14. Internal Pullups and Pulldowns

On-chip 30 k Ω resistors are used to individually set the

LVTTL inputs if these inputs are left unconnected. The

specific default state of each input is enumerated in "Pin

Descriptions: Si5100" on page 26.

15. Power Supply Filtering

The transmitter-generated jitter is most sensitive to

power supply noise below its PLL loop-bandwidth

(BWSEL setting). The power supply noise of interest is

bounded between the SONET/SDH generated jitter

specification of 12 kHz (for 2.48832 Gbps) and the PLL

loop-bandwidth. Integrated supply noise from 1/10th the

SONET/SDH specification (1.2 kHz) to 10x the loop-

bandwidth should be suppressed to a level appropriate

for each design. Below the PLL loop-bandwidth, the

typical generated jitter due to supply noise is

approximately 2.5 mUIpp per 1 mVrms; this parameter

can be used as a guideline for calculating the output

jitter and supply filtering requirements. The receiver

does not place additional power supply constraints

beyond those listed for the transmitter.

Si5100

SI5100-F-BC Silicon Laboratories Inc, SI5100-F-BC Datasheet - Page 21

SI5100-F-BC

Specifications of SI5100-F-BC

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