SI5100-H-GL Silicon Laboratories Inc, SI5100-H-GL Datasheet - Page 14

SI5100-H-GL

Manufacturer Part Number

SI5100-H-GL

Description

IC TXRX SONET/SDH LP HS 195PBGA

Manufacturer

Silicon Laboratories Inc

Series

SiPHY®r

Type

Transceiverr

Datasheet

1.SI5100-H-GL.pdf (40 pages)

Specifications of SI5100-H-GL

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

PHY

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

Lead free / RoHS Compliant

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Manufacturer

Quantity

Price

Company:

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Part Number:

SI5100-H-GL

Manufacturer:

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Quantity:

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Si5100

4. Functional Description

The Si5100 transceiver is a low-power fully-integrated

serializer/deserializer that provides significant margin to

all SONET/SDH jitter specifications. The device

operates from 2.41–2.7 Gbps making it suitable for OC-

48/STM-16

applications that use 255/238 or 255/237 forward error

correction

receive/transmit interface uses a low-power parallel

LVDS interface compatible with LVPECL.

5. Receiver

The receiver within the Si5100 includes a precision

limiting amplifier, a jitter-tolerant clock and data

recovery unit (CDR), and a 1:16 demultiplexer.

Programmable data slicing level and sampling phase

adjustment are provided to support bit-error-rate (BER)

optimization for long-haul applications.

5.1. Receiver Differential Input Circuitry

The receiver serial input provides proper termination

and biasing through two resistor dividers internal to the

device. The active circuitry has high-impedance inputs

and provides sufficient gain for the clock and data

recovery unit to recover the serial data. The input bias

levels are optimized for jitter tolerance and input

sensitivity and are typically not dc compatible with

standard I/Os; simply ac couple the data lines as shown

in Figure 10 on page 22.

5.2. Limiting Amplifier

The Si5100 incorporates a limiting amplifier with

sufficient gain to directly accept the output of

transimpedance amplifiers.

The limiting amplifier provides sufficient gain to fully

saturate with input signals that are greater than 30 mV

peak-to-peak differential. In addition, input signals up to

2 V peak-to-peak differential do not cause any

performance degradation.

5.2.1. Receiver Signal Amplitude Monitoring

The Si5100 limiting amplifier includes circuitry that

monitors the amplitude of the receiver differential input

signal (RXDIN). The RXAMPMON output provides an

analog output signal that is proportional to the input

signal amplitude. The signal is enabled when slice

mode is asserted. The voltage on the RXAMPMON

output is nominally equal to one-half of the differential

peak-to-peak signal amplitude of RXDIN as shown in

Equation 1:

(FEC)

applications

RXAMPMON

Equation 1

coding.

≈

RXDIN PP

and

(

The

)

OC-48/STM-16

.566

low-speed

Rev. 1.4

The receiver signal amplitude monitoring circuit is also

used in the generation of the loss-of-signal alarm (LOS).

5.2.2. Loss-of-Signal Alarm (LOS)

The Si5100 can be configured to activate a loss-of-

signal alarm output (LOS) when the RXDIN input

amplitude drops below a programmable threshold level.

An appropriate level of hysteresis prevents unnecessary

switching on LOS.

The LOS threshold level is set by applying a dc voltage

to the LOSLVL input. The mapping of the voltage on the

LOSLVL pin to the LOS threshold level depends on the

state of the SLICEMODE input. (The SLICEMODE input

is used to select either absolute slice mode or

proportional slice mode operation.)

The LOSLVL mapping for absolute slice mode

(SLICEMODE = 0) is given in Figure 4. The linear

region of the assert can be approximated by the

following equation:

where V

referred to the RXDIN input, and V

applied to the LOSLVL pin.

The linear region of the de-assert curve can be

approximated by the following equation:

The LOSLVL mapping for proportional slice mode

(SLICEMODE = 1) is given in Figure 6 on page 17. The

linear region of the assert can be approximated by the

following equation:

where V

referred to the RXDIN input, and V

applied to the LOSLVL pin.

The linear region of the de-assert curve can be

approximated by the following equation:

The LOS detection circuitry is disabled by tieing the

LOSLVL input to VREF. This forces the LOS output

high.

LOS

is the differential PK-PK LOS threshold

is the differential pk–pk LOS threshold

LOS

Equation 2

Equation 3

Equation 4

Equation 5

≈

LOSLVL

.958

.762

.61

.72

LOSLVL

is the voltage

SI5100-H-GL Silicon Laboratories Inc, SI5100-H-GL Datasheet - Page 14

SI5100-H-GL

Specifications of SI5100-H-GL

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