82V3010PVG Datasheet 82V3010PVG, 82V3010PVG8 | P13-P15

IDT82V3010 T1/E1/OC3 Telecom Clock Generator with Dual Reference Inputs

Functional Description 13 November 14, 2012

Figure - 7 DPLL Block Diagram

In the Normal mode, the Limiter receives the error signal from the

Phase Detector, limits the phase slope within 5 ns per 125 µs and sends

the limited signal to the Loop Filter.

In the Fast Lock mode, the Limiter is disabled, and the DPLL locks to

the input reference within 500 ms, which is much shorter than that in the

Normal mode.

2.7.3 LOOP FILTER

The Loop Filter ensures that the jitter transfer meets the ETS 300

011 and AT&T TR62411 requirements. It works similarly to a first order

low pass filter with 2.1 Hz cutoff frequency for the four valid input

frequencies (8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz).

The output of the Loop Filter goes to the Digital Control Oscillator

directly or through the Fraction blocks, in which E1, T1, C6 and C19

signals are generated.

2.7.4 FRACTION BLOCK

By applying some algorithms to the incoming E1 signal, the

Fraction_C19, Fraction_C6 and Fraction_T1 blocks generate C19, C6

and T1 signals respectively.

2.7.5 DIGITAL CONTROL OSCILLATOR (DCO)

In the Normal mode, the DCO receives four limited and filtered

signals from Loop Filter or Fraction blocks. Based on the values of the

received signals, the DCO generates four digital outputs: 19.44 MHz,

25.248 MHz, 32.768 MHz and 24.704 MHz for C19, C6, E1 and T1

dividers respectively.

In the Holdover mode, the DCO is running at the same frequency as

that generated by storage techniques.

In the Freerun mode, the DCO is running at the same frequency as

that of the master clock.

2.7.6 LOCK INDICATOR

If the output frequency of the DPLL is identical to the input frequency,

and the input phase offset is small enough so that no slope limiting is

exhibited, the LOCK pin will be set high.

2.7.7 OUTPUT INTERFACE

The Output Interface uses three output signals from the DCO to

generate totally 9 types of clock signals and 7 types of framing signals

All these output signals are synchronous to F8o.

Digital Control Oscillator

C32o

C16o

C8o

C4o

C2o

C3o

C6o

F0o

F8o

RSP

TSP

F16o

C1.5o

F32o

Output Interface

T1_Divider

E1_Divider

C6_Divider

Frequency

Selection

Circuit 1

Phase

Detector

Virtual Reference

Fraction_C6

Fraction_T1

24.704 MHz

32.768 MHz

25.248 MHz

Feedback Signal

Limiter

FLOCK F1_sel1 F1_sel0

C19_Divider

155.52 MHz

F19o

C19o

APLL

19.44 MHz

Fraction_C19

C19NEG

C19POS

IN_sel F0_sel1 F0_sel0

Frequency

Selection

Circuit 0

C2/C1.5

Loop Filter

Fx_sel1 Fx_sel0 (x = 0 or 1)

IDT82V3010 T1/E1/OC3 Telecom Clock Generator with Dual Reference Inputs

Functional Description 14 November 14, 2012

The 32.768 MHz signal is used by the E1_divider to generate five

types of clock signals (C2o, C4o, C8o, C16o and C32o) with nominal

50% duty cycle and six types of framing signals (F0o, F8o, F16o, F32o,

RSP and TSP).

The 24.704 MHz signal is used by the T1_divider to generate two

types of T1 signals (C1.5o and C3o) with nominal 50% duty cycle.

The 25.248 MHz signal is used by the C6_divider to generate a C6o

signal with nominal 50% duty cycle.

The 19.44 MHz signal is sent to an APLL, which outputs a 155.52

MHz signal. The 155.52 MHz signal is used by the C19_divider to

generate 19.44 MHz clock signals (C19o, C19POS and C19NEG) with

nominal 50% duty cycle and a framing signal F19o.

Additionally, the IDT82V3010 provides an output clock (C2/C1.5)

with the frequency controlled by the frequency selection pins Fx_sel0

and Fx_sel1 (see Table - 5 for details). If the selected reference input

(Fref0 or Fref1) is 8 kHz, 2.048 MHz or 19.44 MHz, the C2/C1.5 pin will

output a 2.048 MHz clock signal. If the selected reference input (Fref0 or

Fref1) is 1.544 MHz, the C2/C1.5 pin will output a 1.544 MHz clock

signal. The electrical and timing characteristics of this output (2.048

MHz or 1.544 MHz) is the same as that of C2o or C1.5o.

2.8 OSC

The IDT82V3010 can use a clock as the master timing source. In the

Freerun mode, the frequency tolerance of the clock outputs is identical

to that of the source at the OSCi pin. For applications not requiring an

accurate Freerun mode, the tolerance of the master timing source may

be ±100 ppm. For applications requiring an accurate Freerun mode,

such as AT&T TR62411, the tolerance of the master timing source must

be no greater than ±32 ppm.

The desired capture range should be taken into consideration when

determining the accuracy of the master timing source. The sum of the

accuracy of the master timing source and the capture range of the

IDT82V3010 will always equal 230 ppm. For example, if the master

timing source is 100 ppm, the capture range will be 130 ppm.

2.8.1 CLOCK OSCILLATOR

When selecting a Clock Oscillator, numerous parameters must be

considered. This includes absolute frequency, frequency change over

temperature, output rise and fall times, output levels and duty cycle.

For applications requiring ±32 ppm clock accuracy, the following

clock oscillator module may be used.

FOX F7C-2E3-20.0 MHz

Frequency: 20.0 MHz

Tolerance: 25 ppm 0C to 70C

Rise & Fall Time:10 ns (0.33 V, 2.97 V, 15 pF)

Duty Cycle: 40% to 60%

The output clock should be connected directly (not AC coupled) to

the OSCi input of the IDT82V3010, as shown in Figure - 8.

Figure - 8 Clock Oscillator Circuit

2.9 JTAG

The IDT82V3010 supports IEEE 1149.1 JTAG Scan.

2.10 RESET, LOCK AND TIE APPLICATION

A simple power-up reset circuit is shown as Figure - 9. The logic low

reset pulse is about 50 µs.

The resistor Rp is used for protection only and limits current into the

RST pin during power down. The logic low reset pulse width is not

critical but should be greater than 300 ns.

When the DPLL operates in Normal mode after power-up or reset,

the lock pin may indicate frequency lock before the output phase is

synchronized with the input. The phase lock requires 30 seconds (at

most) after frequency lock.

If users want to switch the input reference, it is highly recommended

to do the switch after phase lock, with TIE control block enabled.

After TIE control block is cleared, the DPLL requires some time for

the phase relationship to stabilize. In general, the phase lock requires 30

seconds (at most) after frequency lock.

Figure - 9 Power-Up Reset Circuit

Table - 5 C2/C1.5 Output Frequency Control

Frequency Selection Pins

Frefx Input

Frequency

C2/C1.5 Output

Frequency

Fx_sel1 Fx_sel0

0 0 19.44 MHz 2.048 MHz

0 1 8 kHz 2.048 MHz

1 0 1.544 MHz 1.544 MHz

1 1 2.048 MHz 2.048 MHz

Note: ‘x’ can be 0 or 1, as selected by IN_sel pin.

IN_sel = 0: x = 0, Fref0 is the selected reference input. The frequency of Fref0

is determined by F0_sel0 and F0_sel1 pins.

IN_sel = 1: x = 1, Fref1 is the selected reference input. The frequency of Fref1

is determined by F1_sel0 and F1_sel1 pins.

+3.3 V

20 MHz OUT

GND

+3.3 V

OSCi

IDT82V3010

0.1 F

3.3 V

10 k

1 k

1 F

RST

IDT82V3010

IDT82V3010 T1/E1/OC3 Telecom Clock Generator with Dual Reference Inputs

Functional Description 15 November 14, 2012

2.11 POWER SUPPLY FILTERING TECHNIQUES

Figure - 10 IDT82V3010 Power Decoupling Scheme

As in any high speed analog circuitry, the power supply pins are

vulnerable to random noise. The 82V3010 provides separate power

supplies to isolate any high switching noise from the outputs to the

internal PLL. VDDD and VDDA should be individually connected to the

power supply plane through vias, and bypass capacitors should be used

for each pin. To achieve optimum jitter performance, power supply

isolation is required. Figure - 10 illustrated how bypass capacitor and

ferrite bead should be connected to each power pin.

For the 82V3010, the decoupling for VDDA and VDDD must all be

handled individually. The switching power supply should be filtering with

a large bulk capacitor of 47 uF (1210 case size, ceramic) and a 0.1 uF

(0402 case size, ceramic).

VDDA provides power to the analog circuits. The analog power

supply VDDA should have low impedance. This can be achieved by

using one 10 uF (1210 case size, ceramic) and at least two 0.1 uF (0402

case size, ceramic) capacitors in parallel. The 0.1 uF (0402 case size,

ceramic) capacitors must be placed right next to the VDDA pins as close

as possible. Note that the 10 uF capacitor must be of 1210 case size,

and it must be ceramic for lowest ESR (Effective Series Resistance)

possible. The 0.1 uF should be of case size 0402, this offers the lowest

ESL (Effective Series Inductance) to achieve low impedance towards

the high speed range.

VDDD is the power rail for the core logic as well as I/O driver circuits.

For the VDDD, at least three 0.1 uF (0402 case size, ceramic) and one

10 uF (1210 case size, ceramic) capacitors are recommended. The 0.1

uF capacitors should be placed as close to the VDDD pins as possible.

Please refer to evaluation board schematic for details.

IDT82V3010

3.3V

0.1 F

0.1 F10 F

DDA

DDD

SLF7028T-100M1R1

0.1 F

3. 3V

0.1 F

10 F

SLF7028T-100M1R1

DDD

0.1 F

P1-P3 P4-P6 P7-P9 P10-P12 P13-P15 P16-P18 P19-P21 P22-P24 P25-P27 P28-P30 P31-P31

82V3010PVG

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Clock Generators & Support Products T1/E1/OC3 WAN PLL

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82V3010PVG

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