SI5110-H-BL Silicon Laboratories Inc, SI5110-H-BL Datasheet - Page 18

SI5110-H-BL

Manufacturer Part Number

SI5110-H-BL

Description

IC TXRX SONET/SDH LP HS 99-PBGA

Manufacturer

Silicon Laboratories Inc

Datasheet

1.SI5110-H-BL.pdf (36 pages)

Specifications of SI5110-H-BL

Product

PHY

Supply Voltage (max)

1.89 V, 3.47 V

Supply Voltage (min)

1.71 V

Supply Current

0.7 A

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 20 C

Mounting Style

SMD/SMT

Maximum Power Dissipation

1300 mW

Number Of Channels

Package / Case

BGA-99

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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Manufacturer

Quantity

Price

Company:

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Part Number:

SI5110-H-BL

Manufacturer:

Silicon Laboratories Inc

Quantity:

10 000

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S i 5 11 0

5.6. Auxiliary Clock Output

To support the widest range of system timing

configurations, The Si5110 provides a primary clock

output on RXCLK1 and a secondary clock output

(RXCLK2). The RXCLK2 output can be configured to

provide a clock that is 1/4th or 1/16th the frequency of

the high-speed recovered clock. The divide ratio which

determines the RXCLK2 output frequency is selected by

RXCLK2DIV.

5.7. Receive Data Squelch

During some system error conditions, such as LOS, it

may be desirable to force the receive data output to

zero in order to avoid propagation of erroneous data

into the downstream electronics. The Si5110 provides a

data squelching control input, RXSQLCH, for this

purpose.

When the RXSQLCH input is low, the data outputs

RXDOUT[3:0] are forced to a zero state. The

RXSQLCH input is ignored when the device is operating

in Diagnostic Loopback mode (DLBK = 0).

6. Transmitter

The transmitter consists of a low jitter clock multiplier

unit (CMU) with a 4:1 serializer. The CMU uses a

phase-locked loop (PLL) architecture based on Silicon

Laboratories’ proprietary DSPLL technology. This

technology generates ultra-low jitter clock and data

outputs

SONET/SDH specifications. The DSPLL architecture

also utilizes a digitally implemented loop filter that

eliminates the need for external loop filter components.

As a result, sensitive noise coupling nodes that typically

degrade

environments are removed.

The DSPLL also reduces the complexity and relaxes

the performance requirements for reference clock

distribution circuitry for OC-48/STM-16 optical port

cards. The DSPLL provides selectable wideband and

narrowband loop filter settings that allow the jitter

attenuation characteristics of the CMU to be optimized

for the jitter content of the supplied reference clock. This

allows the CMU to operate with reference clocks that

have relatively high jitter content.

Unlike traditional analog PLL implementations, the loop

filter bandwidth of the Si5110 transmitter CMU is

controlled by a digital filter inside the DSPLL circuit

allowing the bandwidth to be changed without changing

any external component values.

that

jitter

provide

performance

significant

margin

crowded

PCB

the

Rev. 1.4

6.1. DSPLL

The Si5110’s clock multiplier unit (CMU) uses Silicon

Laboratories proprietary DSPLL technology to achieve

optimal jitter performance. The DSPLL implementation

utilizes a digital signal processing (DSP) algorithm to

replace the loop filter commonly found in analog PLL

designs. This algorithm processes the phase detector

error term and generates a digital control value to adjust

the frequency of the voltage-controlled oscillator (VCO).

The DSPLL implementation requires no external loop

filter components. Eliminating sensitive noise entry

points

susceptible to board-level noise sources and makes

SONET/SDH jitter compliance easier to attain in the

application.

The transmit CMU multiplies the frequency of the

selected reference clock up to the serial transmit data

rate. The TXLOL output signal provides an indication of

the transmit CMU lock status. When the CMU has

achieved lock with the selected reference, the TXLOL

output is deasserted (driven high). The TXLOL signal

will be asserted, indicating a transmit CMU loss-of-lock

condition, when a valid clock signal is not detected on

the selected reference clock input. The TXLOL signal

will also be asserted during the transmit CMU frequency

calibration. Calibration is performed automatically when

the Si5110 is powered on, when a valid clock signal is

detected on the selected reference clock input following

a period when no valid clock was present, or when the

frequency of the selected reference clock is outside of

the transmit CMU’s PLL lock range or after RESET is

deasserted.

6.1.1. Programmable Loop Filter Bandwidth

The digitally implemented loop filter allows for four

transmit CMU loop bandwidth settings that provide

wideband or narrowband jitter transfer characteristics.

The filter bandwidth is selected via the BWSEL[1:0]

control inputs. The loop bandwidth choices are listed in

Table 6.

changing the loop filter bandwidth of the Si5110 is

accomplished without the need to change external

component values.

Lower loop bandwidth settings (Narrowband operation)

make the Si5110 more tolerant to jitter on the reference

clock source. As a result, circuitry used to generate and

distribute the physical layer reference clocks can be

simplified

SONET/SDH jitter specifications.

Higher loop bandwidth settings (Wideband operation)

are useful in applications where the reference clock is

provided by a low jitter source like the Si5364 Clock

Synchronization

makes

Unlike

without

Clock Multiplier Unit

the

traditional

compromising

DSPLL

Si5320

PLL

implementation

Precision

margin

implementations,

Clock

less

the

SI5110-H-BL Silicon Laboratories Inc, SI5110-H-BL Datasheet - Page 18

SI5110-H-BL

Specifications of SI5110-H-BL

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