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FemtoClock® NG Universal Frequency

Translator

IDT8T49N203I

DATA SHEET

General Description

Features

The IDT8T49N203I is a highly flexible FemtoClock® NG general

purpose, low phase noise Universal Frequency Translator /

Synthesizer with alarm and monitoring functions suitable for

networking and communications applications. It is able to generate

any output frequency in the 0.98MHz - 312.5MHz range and most

output frequencies in the 312.5MHz - 1,300MHz range (see Table 3

for details). A wide range of input reference clocks and a range of

low-cost fundamental mode crystal frequencies may be used as the

source for the output frequency.

• Fourth generation FemtoClock® NG technology

• Universal Frequency Translator (UFT) / Frequency Synthesizer

• Two outputs, individually programmable as LVPECL or LVDS

• Both outputs may be set to use 2.5V or 3.3V output levels

• Programmable output frequency: 0.98MHz up to 1,300MHz

• Zero ppm frequency translation

• Two differential inputs support the following input types:

LVPECL, LVDS, LVHSTL, HCSL

The IDT8T49N203I has three operating modes to support a very

broad spectrum of applications:

• Input frequency range: 8kHz - 710MHz

• Crystal input frequency range: 16MHz - 40MHz

¹⁾•^FrS^ey^qn^ut^ehⁿe^cs^yize^Ss^yno^tu^ht^ep^suⁱt^zefr^requencies from a 16MHz - 40MHz

• Two factory-set register configurations for power-up default state

• Power-up default configuration pin or register selectable

• Configurations customized via One-Time Programmable ROM

fundamental mode crystal.

• Fractional feedback division is used, so there are no

requirements for any specific crystal frequency to produce the

desired output frequency with a high degree of accuracy.

2

• Settings may be overwritten after power-up via I C

2

• I C Serial interface for register programming

²⁾•^HA^igp^hp^-Blic^aaⁿt^dio^wnⁱs^d:^thPC^FrI^eE^qx^up^erⁿe^cs^ys,^TC^raoⁿm^slp^au^toti^rng, General Purpose

• RMS phase jitter at 155.52MHz, using a 40MHz crystal LVDS

Output (12kHz - 20MHz): 439fs (typical), Low Bandwidth Mode

(FracN)

• Translates any input clock in the 16MHz - 710MHz frequency

range into any supported output frequency.

• RMS phase jitter at 400MHz, using a 40MHz crystal

(12kHz - 40MHz):285fs (typical), Synthesizer Mode (Integer FB)

• This mode has a high PLL loop bandwidth in order to track input

reference changes, such as Spread-Spectrum Clock

modulation, so it will not attenuate much jitter on the input

reference.

• Output supply voltage modes:

V_CC/V_CCA/V_CCO

3.3V/3.3V/3.3V

3.3V/3.3V/2.5V (LVPECL only)

2.5V/2.5V/2.5V

³⁾•^LoA^wp^-p^Bli^acaⁿt^dio^wn^ids^t:^hN^Fe^rt^ew^qo^ur^ekⁿin^cg^y&^TrC^ano^sm^lam^tou^rnications.

• Translates any input clock in the 8kHz -710MHz frequency

• -40°C to 85°C ambient operating temperature

• Available in lead-free (RoHS 6) package

Pin Assignment

range into any supported output frequency.

• This mode supports PLL loop bandwidths in the 10Hz - 580Hz

range and makes use of an external crystal to provide

significant jitter attenuation.

This device provides two factory-programmed default power-up

configurations burned into One-Time Programmable (OTP) memory.

The configuration to be used is selected by the CONFIG pin. The two

configurations are specified by the customer and are programmed by

IDT during the final test phase from an on-hand stock of blank

devices. The two configurations may be completely independent of

one another.

30 29 28 27

23 22 21

26 25 24

31

20

nc

CLK_ACTIVE

nc

32

33

34

35

36

37

38

39

40

19

18

17

16

15

14

13

12

11

IDT8T49N203I

S_A0

S_A1

CONFIG

SCLK

SDATA

V^CC

LF0

40 Lead VFQFN

6mm x 6mm x 0.925mm

K Package

LF1

One usage example might be to install the device on a line card with

two optional daughter cards: an OC-12 option requiring a 622.08MHz

LVDS clock translated from a 19.44MHz input and a Gigabit Ethernet

option requiring a 125MHz LVPECL clock translated from the same

19.44MHz input reference.

VEE

V^CCA

Top View

HOLDOVER

CLK0BAD

CLK1BAD

XTALBAD

PLL_BYPASS

nc

To implement other configurations, these power-up default settings

1

2

3

4

8

9 10

5

6 7

2

can be overwritten after power-up using the I C interface and the

device can be completely reconfigured. However, these settings

would have to be re-written next time the device powers-up.

The Preliminary Information presented herein represents a product in pre-production. The noted characteristics are based on initial product characterization and/or qualification.

Integrated Device Technology, Incorporated (IDT) reserves the right to change any circuitry or specifications without notice

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

1

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Complete Block Diagram

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

2

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Table 1. Pin Descriptions

Number

Name

Type

Description

1

2

XTAL_IN

XTAL_OUT

Crystal Oscillator interface designed for 12pF parallel resonant crystals.

XTAL_IN (pin 1) is the input and XTAL_OUT (pin 2) is the output.

Core supply pins. All must be either 3.3V or 2.5V.

Input

3, 7, 13, 29

V_CC

Power

Input clock select. Selects the active differential clock input. LVCMOS/LVTTL

interface levels.

0 = CLK0, nCLK0 (default)

1 = CLK1, nCLK1

4

CLK_SEL

Input

Pulldown

5

6

CLK0

Input

Pulldown

Non-inverting differential clock input.

Pullup/

Pulldown

Inverting differential clock input. V_CC/2 default when left floating (set by the

internal pullup and pulldown resistors).

nCLK0

8, 21, 35

9

V_EE

Power

Input

Negative supply pins.

CLK1

Pulldown

Non-inverting differential clock input.

Pullup/

Pulldown

Inverting differential clock input. V_CC/2 default when left floating (set by the

internal pullup and pulldown resistors).

10

nCLK1

nc

Input

11, 19,

20, 32

Unused

No connect. These pins are to be left unconnected.

Bypasses the VCXO PLL. In bypass mode, outputs are clocked off the falling

edge of the input reference. LVCMOS/LVTTL interface levels.

0 = PLL Mode (default)

12

PLL_BYPASS

Input

Pulldown

1 = PLL Bypassed

2

14

15

SDATA

SCLK

I/O

Pullup

I C Data Input/Output. Open drain.

2

Input

I C Clock Input. LVCMOS/LVTTL interface levels.

Configuration Pin. Selects between one of two factory programmable pre-set

power-up default configurations. The two configurations can have different

output/input frequency translation ratios, different PLL loop bandwidths, etc.

2

16

CONFIG

Input

Pulldown

These default configurations can be overwritten after power-up via I C if the

user so desires. LVCMOS/LVTTL interface levels.

0 = Configuration 0 (default)

1 = Configuration 1

2

17

18

S_A1

S_A0

Input

Pulldown

I C Address Bit 1. LVCMOS/LVTTL interface levels.

2

I C Address Bit 0. LVCMOS/LVTTL interface levels.

Active High Output Enable for Q1, nQ1. LVCMOS/LVTTL interface levels.

0 = Output pins high-impedance

22

OE1

Input

Pullup

1 = Output switching (default)

Differential output pair. Output type is programmable to LVDS or LVPECL

interface levels.

23, 24

25

nQ1, Q1

V_CCO

Output

Power

Output

Output supply pins for Q1, nQ1 and Q0, nQ0 outputs. Either 2.5V or 3.3V.

Differential output pair. Output type is programmable to LVDS or LVPECL

interface levels.

26, 27

nQ0, Q0

Active High Output Enable for Q0, nQ0. LVCMOS/LVTTL interface levels.

0 = Output pins high-impedance

1 = Output switching (default)

28

30

OE0

Input

Pullup

Lock Indicator - indicates that the PLL is in a locked condition. LVCMOS/LVTTL

interface levels.

LOCK_IND

Output

Indicates which of the two differential clock inputs is currently selected.

LVCMOS/LVTTL interface levels.

0 = CLK0, nCLK0 differential input pair

31

Output

CLK_ACTIVE

1 = CLK1, nCLK1 differential input pair

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

3

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Number

Name

Type

Description

Analog

I/O

33, 34

LF0, LF1

V_CCA

Loop filter connection node pins. LF0 is the output. LF1 is the input.

Analog supply voltage. See Applications section for details on how to connect

this pin.

36

37

Power

Alarm output reflecting if the device is in a holdover state. LVCMOS/LVTTL

interface levels.

0 = Device is locked to a valid input reference

1 = Device is not locked to a valid input reference

HOLDOVER

Output

Alarm output reflecting the state of CLK0. LVCMOS/LVTTL interface levels.

0 = Input Clock 0 is switching within specifications

1 = Input Clock 0 is out of specification

38

39

40

CLK0BAD

CLK1BAD

XTALBAD

Output

Alarm output reflecting the state of CLK1. LVCMOS/LVTTL interface levels.

0 = Input Clock 1 is switching within specifications

1 = Input Clock 1 is out of specification

Alarm output reflecting the state of XTAL. LVCMOS/LVTTL interface levels.

0 = crystal is switching within specifications

1 = crystal is out of specification

NOTE: Pullup and Pulldown refer to internal input resistors. See Table 2, Pin Characteristics, for typical values.

Table 2. Pin Characteristics

Symbol

C_IN

Parameter

Test Conditions

Minimum

Typical

3.5

Maximum

Units

pF

Input Capacitance

Input Pullup Resistor

Input Pulldown Resistor

R_PULLUP

R_PULLDOWN

51

kΩ

51

kΩ

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

4

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Functional Description

The IDT8T49N203I is designed to provide two copies of almost any

desired output frequency within its operating range (0.98 - 1300MHz)

from any input source in the operating range (8kHz - 710MHz). It is

capable of synthesizing frequencies from a crystal or crystal

oscillator source. The output frequency is generated regardless of

the relationship to the input frequency. The output frequency will be

exactly the required frequency in most cases. In most others, it will

only differ from the desired frequency by a few ppb. IDT configuration

software will indicate the frequency error, if any. The IDT8T49N203I

can translate the desired output frequency from one of two input

clocks. Again, no relationship is required between the input and

output frequencies in order to translate to the output clock rate. In this

frequency translation mode, a low-bandwidth, jitter attenuation option

is available that makes use of an external fixed-frequency crystal or

crystal oscillator to translate from a noisy input source. If the input

clock is known to be fairly clean or if some modulation on the input

needs to be tracked, then the high-bandwidth frequency translation

mode can be used, without the need for the external crystal.

ratios within the IDT8T49N203I for the two different card

configurations. Access via I C would not be necessary for operation

using either of the internal configurations.

2

Operating Modes

The IDT8T49N203I has three operating modes which are set by the

MODE_SEL[1:0] bits. There are two frequency translator modes -

low bandwidth and high bandwidth and a frequency synthesizer

mode. The device will operate in the same mode regardless of which

configuration is active.

Please make use of IDT-provided configuration applications to

determine the best operating settings for the desired configurations

of the device.

Output Dividers & Supported Output Frequencies

In all 3 operating modes, the output stage behaves the same way, but

different operating frequencies can be specified in the two

configurations.

The input clock references and crystal input are monitored

continuously and appropriate alarm outputs are raised both as

register bits and hard-wired pins in the event of any

out-of-specification conditions arising. Clock switching is supported

in manual, revertive & non-revertive modes.

The internal VCO is capable of operating in a range anywhere from

1.995GHz - 2.6GHz. It is necessary to choose an integer multiplier of

the desired output frequency that results in a VCO operating

frequency within that range. The output divider stage N[10:0] is

limited to selection of integers from 2 to 2046. Please refer to Table 3

for the values of N applicable to the desired output frequency.

The IDT8T49N203I has two factory-programmed configurations that

may be chosen from as the default operating state after reset. This is

intended to allow the same device to be used in two different

2

applications without any need for access to the I C registers. These

Table 3. Output Divider Settings & Frequency Ranges

2

defaults may be over-written by I C register access at any time, but

Register

Setting

Frequency

Divider

Minimum

f_OUT

Maximum

f_OUT

those over-written settings will be lost on power-down. Please

contact IDT if a specific set of power-up default settings is desired.

Nn[10:0]

N

(MHz)

997.5

665

(MHz)

1300

866.7

650

0000000000x

00000000010

00000000011

00000000100

00000000101

0000000011x

0000000100x

0000000101x

0000000110x

0000000111x

0000001000x

0000001001x

...

2

Configuration Selection

2

3

The IDT8T49N203I comes with two factory-programmed default

configurations. When the device comes out of power-up reset the

selected configuration is loaded into operating registers. The

IDT8T49N203I uses the state of the CONFIG pin or CONFIG register

bit (controlled by the CFG_PIN_REG bit) to determine which

configuration is active. When the output frequency is changed either

via the CONFIG pin or via internal registers, the output behavior may

not be predictable during the register writing and output settling

periods. Devices sensitive to glitches or runt pulses may have to be

reset once reconfiguration is complete.

4

498.75

399

5

520

6

332.5

249.4

199.5

166.3

142.5

124.7

110.8

1995 / N

0.98

433.3

325

8

10

12

14

16

18

Even N

2046

260

216.7

185.7

162.5

144.4

2600 / N

1.27

Once the device is out of reset, the contents of the operating registers

2

can be modified by write access from the I C serial port. Users that

2

have a custom configuration programmed may not require I C

access.

It is expected that the IDT8T49N203I will be used almost exclusively

in a mode where the selected configuration will be used from device

power-up without any changes during operation. For example, the

device may be designed into a communications line card that

supports different I/O modules such as a standard OC-12 module

running at 622.08MHz or a (255/237) FEC rate OC-12 module

running at 669.32MHz. The different I/O modules would result in a

different level on the CONFIG pin which would select different divider

1111111111x

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

5

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

The input reference frequency range is now extended up to 710MHz.

A pre-divider stage P is needed to keep the operating frequencies at

the phase detector within limits.

Frequency Synthesizer Mode

This mode of operation allows an arbitrary output frequency to be

generated from a fundamental mode crystal input. For improved

phase noise performance, the crystal input frequency may be

doubled. As can be seen from the block diagram in Figure 1, only the

upper feedback loop is used in this mode of operation. It is

recommended that CLK0 and CLK1 be left unused in this mode of

operation.

Low-Bandwidth Frequency Translator Mode

As can be seen from the block diagram in Figure 3, this mode

involves two PLL loops. The lower loop with the large integer dividers

is the low bandwidth loop and it sets the output-to-input frequency

translation ratio.This loop drives the upper DCXO loop (digitally

controlled crystal oscillator) via an analog-digital converter.

The upper feedback loop supports a delta-sigma fractional feedback

divider. This allows the VCO operating frequency to be a non-integer

multiple of the crystal frequency. By using an integer multiple only,

lower phase noise jitter on the output can be achieved, however the

use of the delta-sigma divider logic will provide excellent

performance on the output if a fractional divisor is used.

Figure 3. Low Bandwidth Frequency Translator Mode

Block Diagram

The pre-divider stage is used to scale down the input frequency by

an integer value to achieve a frequency in this range. By dividing

down the fed-back VCO operating frequency by the integer divider

M1[16:0] to as close as possible to the same frequency, exact output

frequency translations can be achieved. The phase detector of the

lower loop is designed to work with frequencies in the 8kHz - 16kHz

range. For improved phase noise performance, the crystal input

frequency may be doubled.

Figure 1. Frequency Synthesizer Mode Block Diagram

High-Bandwidth Frequency Translator Mode

This mode of operation is used to translate one of two input clocks of

the same nominal frequency into an output frequency with little jitter

attenuation. As can be seen from the block diagram in Figure 2,

similarly to the Frequency Synthesizer mode, only the upper

feedback loop is used.

Alarm Conditions & Status Bits

The IDT8T49N203I monitors a number of conditions and reports their

status via both output pins and register bits. All alarms will behave as

indicated below in all modes of operation, but some of the conditions

monitored have no valid meaning in some operating modes. For

example, the status of CLK0BAD, CLK1BAD and CLK_ACTIVE are

not relevant in Frequency Synthesizer mode. The outputs will still be

active and it is left to the user to determine which to monitor and how

to respond to them based on the known operating mode.

PLL_BYPASS

Output Divider

1

Q0

÷N[10:0]

FemtoClock® NG

VCO

1995 - 2600 MHz

nQ0

OE0

PD/LF

0

Feedback Divider

Q1

÷M_INT

÷M_FRAC

[17:0]

[7:0]

nQ1

OE1

CLK_ACTIVE - indicates which input clock reference is being used to

derive the output frequency.

CLK_SEL

CLK0

nCLK0

CLK1

nCLK1

0

1

÷P[16:0]

LOCK_IND - This status is asserted on the pin & register bit when the

PLL is locked to the appropriate input reference for the chosen mode

of operation. The status bit will not assert until frequency lock has

been achieved, but will de-assert once lock is lost.

Status Indicators

POR

Control Logic

Global Registers

Register Set 0

Register Set 1

CLK_ACTIVE

LOCK_IND

0

1

CLK0BAD

CLK1BAD

HOLDOVER

CONFIG

SCLK, S_A0, S_A1

SDATA

Figure 2. High Bandwidth Frequency Translator Mode

Block Diagram

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

6

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

XTALBAD - indicates if valid edges are being received on the crystal

input. Detection is performed by comparing the input to the feedback

signal at the upper loop’s Phase / Frequency Detector (PFD). If three

edges are received on the feedback without an edge on the crystal

input, the XTALBAD alarm is asserted on the pin & register bit. Once

an edge is detected on the crystal input, the alarm is immediately

deasserted.

mode) state. In either case, the HOLDOVER alarm will be raised.

This will occur even if there is a valid clock on the non-selected

reference input. The device will recover from holdover / free-run state

once a valid clock is re-established on the selected reference input.

The IDT8T49N203I will only switch input references on command

from the user. The user must either change the CLK_SEL register bit

(if in Manual via Register) or CLK_SEL input pin (if in Manual via Pin).

CLK0BAD - indicates if valid edges are being received on the CLK0

reference input. Detection is performed by comparing the input to the

feedback signal at the appropriate Phase / Frequency Detector

(PFD). When operating in high-bandwidth mode, the feedback at the

upper PFD is used. In low-bandwidth mode, the feedback at the lower

PFD is used. If three edges are received on the feedback without an

edge on the divided down (÷P) CLK0 reference input, the CLK0BAD

alarm is asserted on the pin & register bit. Once an edge is detected

on the CLK0 reference input, the alarm is deasserted.

Automatic Switching Mode

When the AUTO_MAN[1:0] field is set to either of the automatic

selection modes (Revertive or Non-Revertive), the IDT8T49N203I

determines which input reference it prefers / starts from by the state

of the CLK_SEL register bit only. The CLK_SEL input pin is not used

in either Automatic switching mode.

When starting from an unlocked condition, the device will lock to the

input reference indicated by the CLK_SEL register bit. It will not pay

attention to the non-selected input reference until a locked state has

been achieved. This is necessary to prevent ‘hunting’ behavior during

the locking phase.

CLK1BAD - indicates if valid edges are being received on the CLK1

reference input. Behavior is as indicated for the CLK0BAD alarm, but

with the CLK1 input being monitored and the CLK1BAD output pin &

register bits being affected.

Once the IDT8T49N203I has achieved a stable lock, it will remain

locked to the preferred input reference as long as there is a valid clock

on it. If at some point, that clock fails, then the device will

automatically switch to the other input reference as long as there is a

valid clock there. If there is not a valid clock on either input reference,

the IDT8T49N203I will go into holdover (Low Bandwidth Frequency

Translator mode) or free-run (High Bandwidth Frequency Translator

mode) state. In either case, the HOLDOVER alarm will be raised.

HOLDOVER - indicates that the device is not locked to a valid input

reference clock. This can occur in Manual switchover mode if the

selected reference input has gone bad, even if the other reference

input is still good. In automatic mode, this will only assert if both input

references are bad.

Input Reference Selection and Switching

When operating in Frequency Synthesizer mode, the CLK0 and

CLK1 inputs are not used and the contents of this section do not

apply. Except as noted below, when operating in either High or Low

Bandwidth Frequency Translator mode, the contents of this section

apply equally when in either of those modes.

The device will recover from holdover / free-run state once a valid

clock is re-established on either reference input. If clocks are valid on

both input references, the device will choose the reference indicated

by the CLK_SEL register bit.

If running from the non-preferred input reference and a valid clock

returns, there is a difference in behavior between Revertive and

Non-revertive modes. In Revertive mode, the device will switch back

to the reference indicated by the CLK_SEL register bit even if there

is still a valid clock on the non-preferred reference input. In

Both input references CLK0 and CLK1 must be the same nominal

frequency. These may be driven by any type of clock source,

including crystal oscillator modules. A difference in frequency may

cause the PLL to lose lock when switching between input references.

Please contact IDT for the exact limits for your situation.

Non-revertive mode, the IDT8T49N203I will not switch back as long

as the non-preferred input reference still has a valid clock on it.

The global control bits AUTO_MAN[1:0] dictate the order of priority

and switching mode to be used between the CLK0 and CLK1 inputs.

Switchover Behavior of the PLL

Even though the two input references have the same nominal

frequency, there may be minor differences in frequency and

potentially large differences in phase between them. The

IDT8T49N203I will adjust its output to the new input reference. It will

use Phase Slope Limiting to adjust the output phase at a fixed

maximum rate until the output phase and frequency are now aligned

to the new input reference. Phase will always be adjusted by

extending the clock period of the output so that no unacceptably short

clock periods are generated on the output IDT8T49N203I.

Manual Switching Mode

When the AUTO_MAN[1:0] field is set to Manual via Pin, then the

IDT8T49N203I will use the CLK_SEL input pin to determine which

input to use as a reference. Similarly, if set to Manual via Register,

then the device will use the CLK_SEL register bit to determine the

input reference. In either case, the PLL will lock to the selected

reference if there is a valid clock present on that input.

If there is not a valid clock present on the selected input, the

IDT8T49N203I will go into holdover (Low Bandwidth Frequency

Translator mode) or free-run (High Bandwidth Frequency Translator

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

7

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

The two outputs are individually selectable as LVDS or LVPECL

output types via the Q0_TYPE and Q1_TYPE register bits. These

two selection bits are provided in each configuration to allow different

output type settings under each configuration.

Holdover / Free-run Behavior

When both input references have failed (Automatic mode) or the

selected input has failed (Manual mode), the IDT8T49N203I will

enter holdover (Low Bandwidth Frequency Translator mode) or

free-run (High Bandwidth Frequency Translator mode) state . In both

cases, once the input reference is lost, the PLL will stop making

adjustments to the output phase.

The two outputs can be enabled individually also via both register

control bits and input pins. When both the OEn register bit and OEn

pin are enabled, then the appropriate output is enabled. The OEn

register bits default to enabled so that by default the outputs can be

directly controlled by the input pins. Similarly, the input pins are

provisioned with weak pull-ups so that if they are left unconnected,

the output state can be directly controlled by the register bits. When

the differential output is in the disabled state, it will show a high

impedance condition.

If operating in Low Bandwidth Frequency Translation mode, the PLL

will continue to reference itself to the local oscillator and will hold its

output phase and frequency in relation to that source. Output stability

is determined by the stability of the local oscillator in this case.

However, if operating in High Bandwidth Frequency Translation

mode, the PLL no longer has any frequency reference to use and

output stability is now determined by the stability of the internal VCO.

Serial Interface Configuration Description

If the device is programmed to perform Manual switching, once the

selected input reference recovers, the IDT8T49N203I will switch back

to that input reference. If programmed for either Automatic mode, the

device will switch back to whichever input reference has a valid clock

first.

2

The IDT8T49N203I has an I C-compatible configuration interface to

access any of the internal registers (Table 4D) for frequency and PLL

parameter programming. The IDT8T49N203I acts as a slave device

2

on the I C bus and has the address 0b11011xx, where xx is set by the

values on the S_A0 & S_A1 pins (see Table 4A for details). The

interface accepts byte-oriented block write and block read

operations. An address byte (P) specifies the register address (Table

4D) as the byte position of the first register to write or read. Data

bytes (registers) are accessed in sequential order from the lowest to

the highest byte (most significant bit first, see table 4B, 4C). Read

and write block transfers can be stopped after any complete byte

The switchover that results from returning from holdover or free-run

is handled in the same way as a switch between two valid input

references as described in the previous section.

Output Configuration

The two outputs of the IDT8T49N203I both provide the same clock

frequency. Both must operate from the same output voltage level of

3.3V or 2.5V, although this output voltage may be less than or equal

to the core voltage (3.3V or 2.5V) the rest of the device is operating

from. The output voltage level used on the two outputs is supplied on

the V_CCOpin.

2

transfer. It is recommended to terminate I C the read or write transfer

after accessing byte #23.

2

For full electrical I C compliance, it is recommended to use external

pull-up resistors for SDATA and SCLK. The internal pull-up resistors

have a size of 50kΩ typical.

Note: if a different device slave address is desired, please contact

IDT.

2

Table 4A. I C Device Slave Address

1

0

1

S_A1

S_A0

R/W

Table 4B. Block Write Operation

Bit

1

2:8

9

10

11:18

19

20:27

28

29-36

37

...

Slave

Address

Byte (P)

Data Byte

(P)

Data Byte

(P+1)

Data Byte

...

Description

Length (bits)

START

1

W (0)

1

ACK

1

ACK

1

ACK

1

ACK

1

ACK

1

STOP

1

7

8

Table 4C. Block Read Operation

Bit

1

2:8

9

10

11:18

19

20

21:27

28

29

30:37

38

39-46

47

...

A

C

K

A

C

K

A

C

K

A

C

K

A

C

K

A

C

K

Description

Length (bits)

Slave

Address

W

(0)

Address

Byte (P)

Repeate

d START Address

Slave

R

(1)

Data

Byte (P)

DataByte

(P+1)

Data Byte

...

START

1

STOP

1

7

1

8

1

7

1

8

1

8

1

8

1

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

8

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Register Descriptions

Please consult IDT for configuration software and/or programming guides to assist in selection of optimal register settings for the desired

configurations.

2

Table 4D. I C Register Map

Binary

Register

Reg Address

Register Bit

D4

D7

MFRAC0[17]

MFRAC1[17]

MFRAC0[9]

MFRAC1[9]

MFRAC0[1]

MFRAC1[1]

MINT0[1]

MINT1[1]

P0[10]

D6

MFRAC0[16]

MFRAC1[16]

MFRAC0[8]

MFRAC1[8]

MFRAC0[0]

MFRAC1[0]

MINT0[0]

MINT1[0]

P0[9]

D5

MFRAC0[15]

MFRAC1[15]

MFRAC0[7]

MFRAC1[7]

MINT0[7]

MINT1[7]

P0[16]

D3

MFRAC0[13]

MFRAC1[13]

MFRAC0[5]

MFRAC1[5]

MINT0[5]

MINT1[5]

P0[14]

D2

MFRAC0[12]

MFRAC1[12]

MFRAC0[4]

MFRAC1[4]

MINT0[4]

MINT1[4]

P0[13]

D1

MFRAC0[11]

MFRAC1[11]

MFRAC0[3]

MFRAC1[3]

MINT0[3]

MINT1[3]

P0[12]

D0

MFRAC0[10]

MFRAC1[10]

MFRAC0[2]

MFRAC1[2]

MINT0[2]

MINT1[2]

P0[11]

00000

00001

00010

00011

00100

00101

00110

00111

01000

01001

01010

01011

01100

01101

01110

01111

10000

10001

10010

10011

10100

10101

10110

10111

MFRAC0[14]

0

1

MFRAC1[14]

MFRAC0[6]

MFRAC1[6]

MINT0[6]

MINT1[6]

P0[15]

2

3

4

5

6

P1[16]

P1[15]

P1[14]

P1[13]

P1[12]

P1[11]

7

P0[8]

P0[7]

P0[6]

P0[5]

P0[4]

P0[3]

8

P1[10]

P1[9]

P1[8]

P1[7]

P1[6]

P1[5]

P1[4]

P1[3]

9

P0[2]

P0[1]

P0[0]

M1_0[16]

M1_1[16]

M1_0[8]

M1_1[8]

M1_0[0]

M1_1[0]

N0[3]

M1_0[15]

M1_1[15]

M1_0[7]

M1_1[7]

N0[10]

M1_0[14]

M1_1[14]

M1_0[6]

M1_1[6]

N0[9]

M1_0[13]

M1_1[13]

M1_0[5]

M1_1[5]

N0[8]

M1_0[12]

M1_1[12]

M1_0[4]

M1_1[4]

N0[7]

10

11

12

13

14

15

16

17

18

19

20

21

22

23

P1[2]

P1[1]

P1[0]

M1_0[11]

M1_1[11]

M1_0[3]

M1_1[3]

N0[6]

M1_0[10]

M1_1[10]

M1_0[2]

M1_1[2]

N0[5]

M1_0[9]

M1_1[9]

M1_0[1]

M1_1[1]

N0[4]

N1[10]

N1[9]

N1[8]

N1[7]

N0[2]

N0[1]

N0[0]

BW0[6]

N1[6]

N1[5]

N1[4]

N1[3]

N1[2]

N1[1]

N1[0]

BW1[6]

BW0[5]

BW0[4]

BW0[3]

BW1[3]

BW0[2]

BW0[1]

BW0[0]

Q1_TYPE0

Q1_TYPE1

Q0_TYPE0

Q0_TYPE1

BW1[5]

BW1[4]

BW1[2]

BW1[1]

BW1[0]

MODE_SEL[1]

CLK_SEL

1

MODE_SEL[0]

AUTO_MAN[1]

0

CONFIG

AUTO_MAN[0]

1

CFG_PIN_REG

OE1

OE0

ADC_RATE[0]

0

Rsvd

LCK_WIN[1]

0

Rsvd

LCK_WIN[0]

0

ADC_RATE[1]

DBL_XTAL

XTAL_BAD

CLK_ACTIVE

HOLDOVER

CLK1BAD

CLK0BAD

LOCK_IND

Rsvd

Register Bit Color Key

Configuration 0 Specific Bits

Configuration 1 Specific Bits

Global Control & Status Bits

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

9

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

The register bits described in Table 4E are duplicated, with one set

applying for Configuration 0 and the other for Configuration 1. The

functions of the bits are identical, but only apply when the

configuration they apply to is enabled. Replace the lowercase n in the

bit field description with 0 or 1 to find the field’s location in the bitmap

in Table 4D.

Table 4E. Configuration-Specific Control Bits

Register Bits

Function

Determines the output type for output pair Q0, nQ0 for Configuration n.

Q0_TYPEn

0 = LVPECL

1 = LVDS

Determines the output type for output pair Q1, nQ1 for Configuration n.

Q1_TYPEn

0 = LVPECL

1 = LVDS

Pn[16:0]

M1_n[16:0]

M_INTn[7:0]

M_FRACn[17:0]

Nn[10:0]

Reference Pre-Divider for Configuration n.

Integer Feedback Divider in Lower Feedback Loop for Configuration n.

Feedback Divider, Integer Value in Upper Feedback Loop for Configuration n.

Feedback Divider, Fractional Value in Upper Feedback Loop for Configuration n.

Output Divider for Configuration n.

Internal Operation Settings for Configuration n.

Please use IDT IDT8T49N203I Configuration Software to determine the correct settings for these bits for the

specific configuration. Alternatively, please consult with IDT directly for further information on the functions of these

bits.The function of these bits are explained in Tables 4J and 4K.

BWn[6:0]

Table 4F. Global Control Bits

Register Bits

Function

PLL Mode Select

00 = Low Bandwidth Frequency Translator

01 = Frequency Synthesizer

MODE_SEL[1:0]

10 = High Bandwidth Frequency Translator

11 = High Bandwidth Frequency Translator

Configuration Control. Selects whether the configuration selection function is under pin or register control.

CFG_PIN_REG

CONFIG

0 = Pin Control

1 = Register Control

Configuration Selection. Selects whether the device uses the register configuration set 0 or 1. This bit only has an

effect when the CONFIG_PIN_REG bit is set to 1 to enable register control.

Output Enable Control for Output 0. Both this register bit and the corresponding Output Enable pin OE0 must be

asserted to enable the Q0, nQ0 output.

0 = Output Q0, nQ0 disabled

OE0

1 = Output Q0, nQ0 under control of the OE0 pin

Output Enable Control for Output 1. Both this register bit and the corresponding Output Enable pin OE1 must be

asserted to enable the Q1, nQ1 output.

0 = Output Q1, nQ1 disabled

OE1

1 = Output Q1, nQ1 under control of the OE1 pin

Rsvd

Reserved bits - user should write a ‘0’ to these bit positions if a write to these registers is needed

Selects how input clock selection is performed.

00 = Manual Selection via pin only

01 = Automatic, non-revertive

10 = Automatic, revertive

11 = Manual Selection via register only

AUTO_MAN[1:0]

CLK_SEL

In manual clock selection via register mode, this bit will command which input clock is selected. In the automatic

modes, this indicates the primary clock input. In manual selection via pin mode, this bit has no effect.

0 = CLK0

1 = CLK1

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

10

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Sets the ADC sampling rate in Low-Bandwidth Mode as a fraction of the crystal input frequency.

00 = Crystal Frequency / 16

ADC_RATE[1:0]

01 = Crystal Frequency / 8

10 = Crystal Frequency / 4 (recommended)

11 = Crystal Frequency / 2

Sets the width of the window in which a new reference edge must fall relative to the feedback edge: 00 = 2usec

(recommended), 01 = 4usec, 10 = 8usec, 11 = 16usec

LCK_WIN[1:0]

DBL_XTAL

When set, this bit will double the frequency of the crystal input before applying it to the Phase_Frequency Detector.

Table 4G. Global Status Bits

Register Bits

Function

Status Bit for input clock 0. This function is mirrored in the CLK0BAD pin.

0 = input CLK0 is good

CLK0BAD

1 = input CLK0 is bad. Self clears when input clock returns to good status

Status Bit for input clock 1. This function is mirrored in the CLK1BAD pin.

0 = input CLK1 is good

1 = input CLK1 is bad. Self clears when input clock returns to good status

CLK1BAD

XTALBAD

LOCK_IND

Status Bit. This function is mirrored on the XTALBAD pin.

0 = crystal input good

1 = crystal input bad. Self-clears when the XTAL clock returns to good status

Status bit. This function is mirrored on the LOCK_IND pin.

0 = PLL unlocked

1 = PLL locked

Status Bit. This function is mirrored on the HOLDOVER pin.

HOLDOVER

CLK_ACTIVE

0 = Input to phase detector is within specifications and device is tracking to it

1 = Phase detector input is not within specifications and DCXO is frozen at last value

Status Bit. Indicates which input clock is active. Automatically updates during fail-over switching. Status also

indicated on CLK_ACTIVE pin.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

11

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Table 4J. BW[6:0] Bits

Mode

BW[6]

BW[5]

BW[4]

BW[3]

BW[2]

BW[1]

BW[0]

Synthesizer Mode

High-Bandwidth Mode

Low-Bandwidth Mode

PLL2_LF[1]

PLL2_LF[0]

DSM_ORD

DSM_EN

PLL2_CP[1] PLL2_CP[0] PLL2_LOW_ICP

ADC_GAIN[3] ADC_GAIN[2] ADC_GAIN[1] ADC_GAIN[0] PLL1_CP[1] PLL1_CP[0] PLL2_LOW_ICP

Table 4K. Functions of Fields in BW[6:0]

Register Bits

PLL2_LF[1:0]

DSM_ORD

Function

Sets loop filter values for upper loop PLL in Frequency Synthesizer & High-Bandwidth modes.

Defaults to setting of 00 when in Low Bandwidth Mode. See Table 4L for settings.

Sets Delta-Sigma Modulation to 2nd (0) or 3rd order (1) operation

Enables Delta-Sigma Modulator

DSM_EN

0 = Disabled - feedback in integer mode only

1 = Enabled - feedback in fractional mode

Upper loop PLL charge pump current settings:

00 = 173µA (defaults to this setting in Low Bandwidth Mode)

PLL2_CP[1:0]

01 = 346µA

10 = 692µA

11 = reserved

Reduces Charge Pump current by 1/3 to reduce bandwidth variations resulting from higher feedback register

settings or high VCO operating frequency (>2.4GHz).

PLL2_LOW_ICP

ADC_GAIN[3:0]

Gain setting for ADC in Low Bandwidth Mode.

Lower loop PLL charge pump current settings (lower loop is only used in Low Bandwidth Mode):

00 = 800µA

01 = 400µA

10 = 200µA

11 = 100µA

PLL1_CP[1:0]

Table 4L. High Bandwidth Frequency and Frequency Synthesizer Bandwidth Settings

Desired Bandwidth

PLL2_CP

PLL2_LOW_ICP

PLL2_LF

Frequency Synthesizer Mode

200kHz

400kHz

800kHz

2MHz

00

01

10

1

00

01

10

11

High Bandwidth Frequency Translator Mode

200kHz

400kHz

800kHz

4MHz

00

01

10

1

0

00

01

10

11

NOTE: To achieve 4MHz bandwidth, reference to the phase detector should be 80MHz.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

12

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Absolute Maximum Ratings

NOTE: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.

These ratings are stress specifications only. Functional operation of product at these conditions or any conditions beyond

those listed in the DC Characteristics or AC Characteristics is not implied. Exposure to absolute maximum rating conditions for

extended periods may affect product reliability.

Item

Rating

Supply Voltage, V_CC

3.63V

Inputs, V_I

XTAL_IN

0V to 2V

Other Inputs

-0.5V to V_CC+ 0.5V

Outputs, V_O(LVCMOS)

-0.5V to V_CCO+ 0.5V

Outputs, I_O(LVPECL)

Continuous Current

Surge Current

50mA

100mA

Outputs, I_O(LVDS)

Continuous Current

Surge Current

10mA

15mA

Package Thermal Impedance, θ_JA

32.4°C/W (0 mps)

-65°C to 150°C

Storage Temperature, T_STG

DC Electrical Characteristics

Table 5A. LVPECL Power Supply DC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

V_CC

Parameter

Test Conditions

Minimum

3.135

Typical

3.3

Maximum

3.465

V_CC

Units

V

Core Supply Voltage

Analog Supply Voltage

Output Supply Voltage

Power Supply Current

Analog Supply Current

V_CCA

V_CCO

I_EE

V_CC– 0.30

3.135

3.3

V

3.3

3.465

332

V

mA

I_CCA

30

Table 5B. LVPECL Power Supply DC Characteristics, V_CC= 3.3V 5ꢀ, V_CCO= 2.5V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

V_CC

Parameter

Test Conditions

Minimum

3.135

Typical

3.3

Maximum

3.465

V_CC

Units

V

Core Supply Voltage

Analog Supply Voltage

Output Supply Voltage

Power Supply Current

Analog Supply Current

V_CCA

V_CCO

I_EE

V_CC– 0.30

2.375

3.3

V

2.5

2.625

332

V

mA

I_CCA

30

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

13

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Table 5C. LVPECL Power Supply DC Characteristics, V_CC= V_CCO= 2.5V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

V_CC

Parameter

Test Conditions

Minimum

2.375

Typical

2.5

Maximum

2.625

V_CC

Units

V

Core Supply Voltage

Analog Supply Voltage

Output Supply Voltage

Power Supply Current

Analog Supply Current

V_CCA

V_CCO

I_EE

V_CC– 0.26

2.375

2.5

V

2.5

2.625

319

V

mA

I_CCA

26

Table 5D. LVDS Power Supply DC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ, T_A= -40°C to 85°C

Symbol

V_CC

Parameter

Test Conditions

Minimum

3.135

Typical

3.3

Maximum

3.465

V_CC

Units

V

Core Supply Voltage

Analog Supply Voltage

Output Supply Voltage

Power Supply Current

Analog Supply Current

Output Supply Current

V_CCA

V_CCO

I_CC

V_CC– 0.30

3.135

3.3

V

3.3

3.465

284

V

mA

I_CCA

30

I_CCO

40

Table 5E. LVDS Power Supply DC Characteristics, V_CC= V_CCO= 2.5V 5ꢀ, T_A= -40°C to 85°C

Symbol

V_CC

Parameter

Test Conditions

Minimum

2.375

Typical

2.5

Maximum

2.625

V_CC

Units

V

Core Supply Voltage

Analog Supply Voltage

Output Supply Voltage

Power Supply Current

Analog Supply Current

Output Supply Current

V_CCA

V_CCO

I_CC

V_CC– 0.26

2.375

2.5

V

2.5

2.625

275

V

mA

I_CCA

26

I_CCO

40

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

14

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Table 5F. LVCMOS/LVTTL DC Characteristics, T_A= -40°C to 85°C

Symbol Parameter

Test Conditions

_CC= 3.3V

V_CC= 2.5V

Minimum

Typical

Maximum

V_CC+ 0.3

0.8

Units

V

2

V

V_IH

V_IL

Input High Voltage

1.7

-0.3

V

_CC= 3.3V

_CC= 2.5V

Input Low Voltage

CLK_SEL, CONFIG,

V

0.7

V

_CC= V_IN= 3.465V or 2.625V

150

5

µA

PLL_BYPASS, S_A[0:1]

Input

High Current

I_IH

OE0, OE1,

SCLK, SDATA

V_CC= V_IN= 3.465V or 2.625V

CLK_SEL, CONFIG,

PLL_BYPASS, S_A[0:1]

V_CC= 3.465V or 2.625V,

V_IN= 0V

-5

Input

Low Current

I_IL

OE0, OE1,

SCLK, SDATA

V_CC= 3.465V or 2.625V,

V_IN= 0V

-150

2.6

µA

V

HOLDOVER, SDATA

CLK_ACTIVE,

LOCK_IND, XTALBAD,

CLK0BAD, CLK1BAD

V_CC= 3.3V 5ꢀ, I_OH= -8mA

Output

High Voltage

V_OH

V

_CC= 2.5V 5ꢀ, I_OH= -8mA

1.8

V

HOLDOVER, SDATA

CLK_ACTIVE,

LOCK_IND, XTALBAD,

CLK0BAD, CLK1BAD

Output

Low Voltage

V_CC= 3.3V 5ꢀ or

2.5V 5ꢀ, I_OL= 8mA

V_OL

0.5

V

Table 5G. Differential DC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ or 2.5V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

Parameter

Input

Test Conditions

Minimum

Typical

Maximum

Units

CLK0, nCLK0,

CLK1, nCLK1

CLK0, CLK1

I_IH

V_CC= V_IN= 3.465V or 2.625V

150

µA

High Current

V_CC= 3.465V or 2.625V, V_IN= 0V

-5

µA

V

Input

I_IL

Low Current

nCLK0, nCLK1

-150

0.15

V_PP

V_CMR

Peak-to-Peak Voltage; Note 1

Common Mode Input Voltage;

NOTE 1, 2

1.3

V_EE+ 0.5

V_CC- 1.0

V

NOTE 1: V_ILshould not be less than -0.3v.

NOTE 2: Common mode input voltage is defined as the crosspoint.

Table 5H. LVPECL DC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

V_OH

Parameter

Test Conditions

Minimum

V_CCO– 1.1

V_CCO– 2.0

0.6

Typical

Maximum

V_CCO– 0.7

V_CCO– 1.5

1.0

Units

Output High Voltage; NOTE 1

Output Low Voltage NOTE 1

Peak-to-Peak Output Voltage Swing

V

V_OL

V_SWING

NOTE 1: Outputs terminated with 50Ω to V_CCO– 2V.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

15

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Table 5I. LVPECL DC Characteristics, V_CC= 3.3V 5ꢀ or 2.5V 5ꢀ, V_CCO= 2.5V 5ꢀ, V_EE= 0V, T_A= -40°C to 85°C

Symbol

V_OH

Parameter

Test Conditions

Minimum

V_CCO– 1.1

V_CCO– 2.0

0.6

Typical

Maximum

V_CCO– 0.8

V_CCO– 1.5

1.0

Units

Output High Voltage; NOTE 1

Output Low Voltage NOTE 1

Peak-to-Peak Output Voltage Swing

V

V_OL

V_SWING

NOTE 1: Outputs terminated with 50Ω to V_CCO– 2V.

Table 5J. LVDS DC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ, T_A= -40°C to 85°C

Symbol

V_OD

Parameter

Test Conditions

Minimum

Typical

Maximum

454

Units

mV

V

Differential Output Voltage

V_ODMagnitude Change

Offset Voltage

247

∆V_OD

V_OS

50

1.125

1.375

50

∆V_OS

V_OSMagnitude Change

mV

Table 5K. LVDS DC Characteristics, V_CC= V_CCO= 2.5V 5ꢀ, T_A= -40°C to 85°C

Symbol

V_OD

Parameter

Test Conditions

Minimum

Typical

Maximum

454

Units

mV

V

Differential Output Voltage

V_ODMagnitude Change

Offset Voltage

247

∆V_OD

V_OS

50

1.125

1.375

50

∆V_OS

V_OSMagnitude Change

mV

Table 6. Input Frequency Characteristics, V_CC= V_CCO= 3.3V 5ꢀ, T_A= -40°C to 85°C

Symbol

Parameter

Test Conditions

Minimum

Typical

Maximum

Units

XTAL_IN, XTAL_OUT

NOTE 1

16

40

MHz

Input

Frequency

High Bandwidth Mode

Low Bandwidth Mode

16

710

5

MHz

f_IN

CLK0, nCLK0,

CLK1, nCLK1

0.008

SCLK

NOTE 1: For the input crystal and CLKx, nCLKx frequency range, the M value must be set for the VCO to operate within the 1995MHz to

2600MHz range.

Table 7. Crystal Characteristics

Parameter

Test Conditions

Minimum

Typical

Maximum

Units

Mode of Oscillation

Frequency

Fundamental

16

40

100

7

MHz

Ω

Equivalent Series Resistance (ESR)

Shunt Capacitance

Load Capacitance (CL)

pF

12

pF

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

16

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

AC Electrical Characteristics

Table 8. AC Characteristics, V_CC= V_CCO= 3.3V 5ꢀ or 2.5V 5ꢀ, or

V

_CC= 3.3V 5ꢀ, V_CCO= 2.5V 5ꢀ (LVPECL Only), V_EE= 0V, T_A= -40°C to 85°C

Symbol Parameter

Test Conditions

Minimum

Typical

Maximum

Units

f_OUT

Output Frequency

0.98

1300

MHz

Synth Mode (Integer FB),

f_OUT= 400MHz, 40MHz XTAL,

Integration Range: 12kHz – 40MHz

285

363

313

446

521

490

fs

Synth Mode (FracN FB),

f_OUT= 698.81MHz, 40MHz XTAL,

Integration Range: 12kHz – 20MHz

HBW Mode, (NOTE 1)

f_IN= 133.33MHz, f_OUT= 400MHz,

RMS Phase Jitter;

Integer Divide Ratio

tjit(Ø)

Integration Range: 12kHz – 20MHz

LBW Mode (FracN), 40MHz XTAL,

f

_IN= 19.44MHz, f_OUT= 155.52MHz,

Integration Range: 12kHz – 20MHz

(LVDS Output)

439

450

670

fs

LBW Mode (FracN), 40MHz XTAL,

f_IN= 25MHz, f_OUT= 161.1328125MHz,

Integration Range: 12kHz – 20MHz

(LVDS Output)

LVPECL Outputs

LVDS Output

2.2

5.1

5.3

8.7

30

ps

ꢀ

tjit(per)

RMS Period Jitter NOTE 5

Frequency Synthesizer Mode

Frequency Translator Mode

tjit(cc)

tsk(o)

t_R/ t_F

Cycle-to-Cycle Jitter; NOTE 2

Output Skew; NOTE 2, 3

40

42

LVPECL Outputs

LVDS Outputs

20ꢀ to 80ꢀ

100

80

520

55

Output

Rise/Fall Time

f_OUT< 600MHz

45

odc

Output Duty Cycle

f

_OUT≥ 600MHz

40

60

ꢀ

from falling edge of the 8th SCLK for a

register change

200

10

ns

Output Re-configuration Settling

Time

t_SET

from edge on CONFIG pin

NOTE: Electrical parameters are guaranteed over the specified ambient operating temperature range, which is established when the device is

mounted in a test socket with maintained transverse airflow greater than 500 lfpm. The device will meet specifications after thermal equilibrium

has been reached under these conditions.

NOTE 1: Measured using a Rohde & Schwarz SMA100 Signal Generator, 9kHz to 6GHz as the input source.

NOTE 2: This parameter is defined in accordance with JEDEC Standard 65.

NOTE 3: Defined as skew between outputs at the same supply voltage and with equal load conditions. Measured at the output differential

cross points.

NOTE 4: RMS Phase Jitter are measured with DBL_XTAL bit set to 1 and crystal CL = 12pf.

NOTE 5: This parameter is defined in accordance with Jedec Standard 65.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

17

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Typical Phase Noise at 400MHz (HBW Mode)

400MHz

RMS Phase Jitter

12kHz to 40MHz = 258fs (typical)

Offset Frequency (Hz)

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

18

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Parameter Measurement Information

2V

SCOPE

V

CC,

V

CCO

CC,

Qx

V

CCO

V

CCA

V

CCA

nQx

V_EE

-1.3V+0.165V

-0.5V 0.125V

2.5 Core/2.5V LVPECL Output Load Test Circuit

3.3 Core/3.3V LVPECL Output Load Test Circuit

2.8V 0.04V

2V

2.8V 0.04V

SCOPE

V

CC

SCOPE

Qx

V

Qx

CC,

V

3.3V 5ꢀ

CCO

POWER SUPPLY

V

CCO

V

CCA

+

Float GND –

nQx

V_EE

-0.5V 0.125V

3.3 Core/3.3V LVDS Output Load Test Circuit

3.3 Core/2.5V LVPECL Output Load Test Circuit

V

CC

SCOPE

V

Qx

CC,

nCLKx

2.5V 5ꢀ

POWER SUPPLY

V

CCO

V

CCA

V_PP

Cross Points

+

Float GND –

CLKx

nQx

V_CMR

V

EE

2.5 Core/2.5V LVDS Output Load Test Circuit

Differential Input Levels

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

19

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Parameter Measurement Information, continued

Phase Noise Plot

nQx

Qx

nQy

Qy

Offset Frequency

tsk(o)

f₁

f₂

RMS Phase Jitter =

1

*

Area Under Curve Defined by the Offset Frequency Markers

2 * * ƒ

RMS Phase Jitter

Output Skew

nQx

Qx

nQx

t_PW

Qx

t_PERIOD

➤

tcycle n

tcycle n+1

➤

t_PW

tjit(cc) = tcycle n – tcycle n+1

|

odc =

x 100ꢀ

1000 Cycles

t_PERIOD

Cycle-to-Cycle Jitter

Differential Output Duty Cycle/Output Pulse Width/Period

nQx

80ꢀ

t_F

80ꢀ

t_F

80ꢀ

t_R

80ꢀ

V_SWING

20ꢀ

V_OD

20ꢀ

Qx

t_R

LVDS Output Rise/Fall Time

LVPECL Output Rise/Fall Time

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

20

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Parameter Measurement Information, continued

Offset Voltage Setup

V_DD

V_OH

out

V_REF

DC Input

100

LVDS

V_OL

1σ contains 68.26ꢀ of all measurements

2σ contains 95.4ꢀ of all measurements

3σ contains 99.73ꢀ of all measurements

4σ contains 99.99366ꢀ of all measurements

6σ contains (100-1.973x10^-7)ꢀ of all measurements

Histogram

Reference Point

(Trigger Edge)

Mean Period

(First edge after trigger)

Differential Output Voltage Setup

Period Jitter

V_DD

out

DC Input

LVDS

out

V_OS/∆ V_OS

ä

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

21

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Applications Information

Recommendations for Unused Input and Output Pins

Inputs:

Outputs:

Crystal Inputs

LVPECL Outputs

All unused LVPECL outputs can be left floating. We recommend that

there is no trace attached. Both sides of the differential output pair

should either be left floating or terminated.

For applications not requiring the use of the crystal oscillator input,

both XTAL_IN and XTAL_OUT can be left floating. Though not

required, but for additional protection, a 1kΩ resistor can be tied from

XTAL_IN to ground.

LVDS Outputs

All unused LVDS output pairs can be either left floating or terminated

with 100Ω across. If they are left floating there should be no trace

attached.

CLKx/nCLKx Inputs

For applications not requiring the use of either differential input, both

CLKx and nCLKx can be left floating. Though not required, but for

additional protection, a 1kΩ resistor can be tied from CLKx to ground.

It is recommended that CLKx, nCLKx be left unconnected in

frequency synthesizer mode.

LVCMOS Outputs

All unused LVCMOS output can be left floating. There should be no

trace attached.

LVCMOS Control Pins

All control pins have internal pullups or pulldowns; additional

resistance is not required but can be added for additional protection.

A 1kΩ resistor can be used.

Recommended Values for Low-Bandwidth Mode Loop Filter

External loop filter components are not needed in Frequency

Synthesizer or High-Bandwidth modes. In Low-Bandwidth mode, the

loop filter structure and components shown in Figure 11 are

recommended. Please consult IDT if other values are needed.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

22

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Wiring the Differential Input to Accept Single-Ended Levels

Figure 4 shows how a differential input can be wired to accept single

ended levels. The reference voltage V_REF= V_CC/2 is generated by

the bias resistors R1 and R2. The bypass capacitor (C1) is used to

help filter noise on the DC bias. This bias circuit should be located as

close to the input pin as possible. The ratio of R1 and R2 might need

to be adjusted to position the V_REFin the center of the input voltage

swing. For example, if the input clock swing is 2.5V and V_CC= 3.3V,

R1 and R2 value should be adjusted to set V_REFat 1.25V. The values

below are for when both the single ended swing and V_CCare at the

same voltage. This configuration requires that the sum of the output

impedance of the driver (Ro) and the series resistance (Rs) equals

the transmission line impedance. In addition, matched termination at

the input will attenuate the signal in half. This can be done in one of

two ways. First, R3 and R4 in parallel should equal the transmission

line impedance. For most 50Ω applications, R3 and R4 can be 100Ω.

The values of the resistors can be increased to reduce the loading for

slower and weaker LVCMOS driver. When using single-ended

signaling, the noise rejection benefits of differential signaling are

reduced. Even though the differential input can handle full rail

LVCMOS signaling, it is recommended that the amplitude be

reduced. The datasheet specifies a lower differential amplitude,

however this only applies to differential signals. For single-ended

applications, the swing can be larger, however V_ILcannot be less

than -0.3V and V_IHcannot be more than V_CC+ 0.3V. Though some

of the recommended components might not be used, the pads

should be placed in the layout. They can be utilized for debugging

purposes. The datasheet specifications are characterized and

guaranteed by using a differential signal.

Figure 4. Recommended Schematic for Wiring a Differential Input to Accept Single-ended Levels

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

23

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Overdriving the XTAL Interface

The XTAL_IN input can be overdriven by an LVCMOS driver or by one

side of a differential driver through an AC coupling capacitor. The

XTAL_OUT pin can be left floating. The amplitude of the input signal

should be between 500mV and 1.8V and the slew rate should not be

less than 0.2V/nS. For 3.3V LVCMOS inputs, the amplitude must be

reduced from full swing to at least half the swing in order to prevent

signal interference with the power rail and to reduce internal noise.

Figure 5A shows an example of the interface diagram for a high

speed 3.3V LVCMOS driver. This configuration requires that the sum

of the output impedance of the driver (Ro) and the series resistance

(Rs) equals the transmission line impedance. In addition, matched

termination at the crystal input will attenuate the signal in half. This

can be done in one of two ways. First, R1 and R2 in parallel should

equal the transmission line impedance. For most 50Ω applications,

R1 and R2 can be 100Ω. This can also be accomplished by removing

R1 and changing R2 to 50Ω. The values of the resistors can be

increased to reduce the loading for a slower and weaker LVCMOS

driver. Figure 5B shows an example of the interface diagram for an

LVPECL driver. This is a standard LVPECL termination with one side

of the driver feeding the XTAL_IN input. It is recommended that all

components in the schematics be placed in the layout. Though some

components might not be used, they can be utilized for debugging

purposes. The datasheet specifications are characterized and

guaranteed by using a quartz crystal as the input.

VCC

XTAL_OUT

R1

100

C1

Rs

Zo = 50 ohms

Ro

XTAL_IN

.1uf

R2

100

Zo = Ro + Rs

LVCMOS Driver

Figure 5A. General Diagram for LVCMOS Driver to XTAL Input Interface

XTAL_OUT

C2

Zo = 50 ohms

XTAL_I N

.1uf

Zo = 50 ohms

R1

50

R2

50

LVPECL Driver

R3

50

Figure 5B. General Diagram for LVPECL Driver to XTAL Input Interface

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

24

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Differential Clock Input Interface

The CLK /nCLK accepts LVDS, LVPECL, LVHSTL, HCSL and other

differential signals. Both V_SWINGand V_OHmust meet the V_PPand

V_CMRinput requirements. Figures 6A to 6E show interface examples

for the CLK/nCLK input driven by the most common driver types. The

input interfaces suggested here are examples only. Please consult

with the vendor of the driver component to confirm the driver

termination requirements. For example, in Figure 6A, the input

termination applies for IDT open emitter LVHSTL drivers. If you are

using an LVHSTL driver from another vendor, use their termination

recommendation.

3.3V

1.8V

Zo = 50Ω

CLK

Zo = 50Ω

nCLK

Differential

Input

nCLK

LVPECL

Differential

R1

R2

LVHSTL

50Ω

Input

R1

50Ω

R2

50Ω

IDT

LVHSTL Driver

R2

50Ω

Figure 6A. CLK/nCLK Input

Figure 6B. CLK/nCLK Input

Driven by an IDT Open Emitter LVHSTL Driver

Driven by a 3.3V LVPECL Driver

3.3V

R3

R4

3.3V

125Ω

Zo = 50Ω

CLK

R1

100Ω

nCLK

Zo = 50Ω

Differential

Input

LVPECL

Receiver

LVDS

R1

R2

84Ω

Figure 6C. CLK/nCLK Input

Figure 6D. CLK/nCLK Input

Driven by a 3.3V LVDS Driver

Driven by a 3.3V LVPECL Driver

3.3V

Zo = 50Ω

*R3

*R4

33Ω

CLK

Zo = 50Ω

nCLK

Differential

Input

HCSL

R1

50Ω

R2

50Ω

*Optional – R3 and R4 can be 0Ω

Figure 6E. CLK/nCLK Input

Driven by a 3.3V HCSL Driver

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

25

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

LVDS Driver Termination

For a general LVDS interface, the recommended value for the

termination impedance (Z_T) is between 90Ω and 132Ω. The actual

value should be selected to match the differential impedance (Z₀) of

your transmission line. A typical point-to-point LVDS design uses a

100Ω parallel resistor at the receiver and a 100Ω differential

transmission-line environment. In order to avoid any

transmission-line reflection issues, the components should be

surface mounted and must be placed as close to the receiver as

possible. IDT offers a full line of LVDS compliant devices with two

types of output structures: current source and voltage source. The

standard termination schematic as shown in Figure 7A can be used

with either type of output structure. Figure 7B, which can also be

used with both output types, is an optional termination with center tap

capacitance to help filter common mode noise. The capacitor value

should be approximately 50pF. If using a non-standard termination, it

is recommended to contact IDT and confirm if the output structure is

current source or voltage source type. In addition, since these

outputs are LVDS compatible, the input receiver’s amplitude and

common-mode input range should be verified for compatibility with

the output.

Z_O≈ Z_T

LVDS

Receiver

LVDS

Driver

Z_T

Figure 7A. Standard Termination

Z_T

Z_O≈ Z_T

LVDS

Driver

2

Z_T

2

LVDS

Receiver

C

Figure 7B. Optional Termination

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

26

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Termination for 3.3V LVPECL Outputs

The clock layout topology shown below is a typical termination for

LVPECL outputs. The two different layouts mentioned are

recommended only as guidelines.

transmission lines. Matched impedance techniques should be used

to maximize operating frequency and minimize signal distortion.

Figures 8A and 8B show two different layouts which are

recommended only as guidelines. Other suitable clock layouts may

exist and it would be recommended that the board designers

simulate to guarantee compatibility across all printed circuit and clock

component process variations.

The differential outputs are low impedance follower outputs that

generate ECL/LVPECL compatible outputs. Therefore, terminating

resistors (DC current path to ground) or current sources must be

used for functionality. These outputs are designed to drive 50Ω

3.3V

R3

R4

3.3V

125Ω

3.3V

Z

_o= 50Ω

3.3V

+

_

Z

_o= 50Ω

+

_

Input

LVPECL

Input

Z

_o= 50Ω

R1

R2

50Ω

R1

84Ω

R2

84Ω

V_CC- 2V

1

RTT =

* Z_o

RTT

((V_OH+ V_OL) / (V_CC– 2)) – 2

Figure 8A. 3.3V LVPECL Output Termination

Figure 8B. 3.3V LVPECL Output Termination

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

27

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Termination for 2.5V LVPECL Outputs

Figure 9A and Figure 9B show examples of termination for 2.5V

LVPECL driver. These terminations are equivalent to terminating 50Ω

to V_CCO– 2V. For V_CCO= 2.5V, the V_CCO– 2V is very close to ground

level. The R3 in Figure 9B can be eliminated and the termination is

shown in Figure 9C.

2.5V

V_CCO= 2.5V

2.5V

V_CCO= 2.5V

R1

R3

50Ω

250

+

50Ω

+

–

50Ω

–

2.5V LVPECL Driver

R1

50

R2

50

2.5V LVPECL Driver

R2

62.5

R4

62.5

R3

18

Figure 9A. 2.5V LVPECL Driver Termination Example

Figure 9B. 2.5V LVPECL Driver Termination Example

2.5V

V_CCO= 2.5V

50Ω

+

50Ω

–

2.5V LVPECL Driver

R1

50

R2

50

Figure 9C. 2.5V LVPECL Driver Termination Example

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

28

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

VFQFN EPAD Thermal Release Path

In order to maximize both the removal of heat from the package and

the electrical performance, a land pattern must be incorporated on

the Printed Circuit Board (PCB) within the footprint of the package

corresponding to the exposed metal pad or exposed heat slug on the

package, as shown in Figure 10. The solderable area on the PCB, as

defined by the solder mask, should be at least the same size/shape

as the exposed pad/slug area on the package to maximize the

thermal/electrical performance. Sufficient clearance should be

designed on the PCB between the outer edges of the land pattern

and the inner edges of pad pattern for the leads to avoid any shorts.

and dependent upon the package power dissipation as well as

electrical conductivity requirements. Thus, thermal and electrical

analysis and/or testing are recommended to determine the minimum

number needed. Maximum thermal and electrical performance is

achieved when an array of vias is incorporated in the land pattern. It

is recommended to use as many vias connected to ground as

possible. It is also recommended that the via diameter should be 12

to 13mils (0.30 to 0.33mm) with 1oz copper via barrel plating. This is

desirable to avoid any solder wicking inside the via during the

soldering process which may result in voids in solder between the

exposed pad/slug and the thermal land. Precautions should be taken

to eliminate any solder voids between the exposed heat slug and the

land pattern. Note: These recommendations are to be used as a

guideline only. For further information, please refer to the Application

Note on the Surface Mount Assembly of Amkor’s Thermally/

Electrically Enhance Lead frame Base Package, Amkor Technology.

While the land pattern on the PCB provides a means of heat transfer

and electrical grounding from the package to the board through a

solder joint, thermal vias are necessary to effectively conduct from

the surface of the PCB to the ground plane(s). The land pattern must

be connected to ground through these vias. The vias act as “heat

pipes”. The number of vias (i.e. “heat pipes”) are application specific

SOLDER

EXPOSED HEAT SLUG

PIN PAD

GROUND PLANE

LAND PATTERN

(GROUND PAD)

PIN PAD

THERMAL VIA

Figure 10. P.C. Assembly for Exposed Pad Thermal Release Path – Side View (drawing not to scale)

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

29

IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

Schematic Layout

Figure 11 (next page), shows an example of the UFT

In order to achieve the best possible filtering, it is recommended that

the placement of the filter components be on the device side of the

PCB as close to the power pins as possible. If space is limited, the

0.1uf capacitor in each power pin filter should be placed on the device

side. The other components can be on the opposite side of the PCB.

(IDT8T49N203I) application schematic. Input and output

terminations shown are intended as examples only and may not

represent the exact user configuration. In this example, the device is

operated at V_CC= 3.3V. For 2.5V option, please refer to the

“Termination for 2.5V LVPECL Outputs” for output termination

recommendation. The decoupling capacitors should be located as

close as possible to the power pin. A 12pF parallel resonant 16MHz

to 40MHz crystal is used in this example. Different crystal

frequencies may be used. The C1 = C2 = 5pF are recommended for

frequency accuracy. If different crystal types are used, please consult

IDT for recommendations. For different board layout, the C1 and C2

may be slightly adjusted for optimizing frequency accuracy. It is

recommended that the loop filter components be laid out for the

3-pole option. This will also allow either 2-pole or 3-pole filter to be

used. The 3-pole filter can be used for additional spur reduction. If a

2-pole filter construction is used, the LF0 and LF1 pins must be

tied-together to the filter.

Power supply filter recommendations are a general guideline to be

used for reducing external noise from coupling into the devices. The

filter performance is designed for a wide range of noise frequencies.

This low-pass filter starts to attenuate noise at approximately 10 kHz.

If a specific frequency noise component is known, such as switching

power supplies frequencies, it is recommended that component

values be adjusted and if required, additional filtering be added.

Additionally, good general design practices for power plane voltage

stability suggests adding bulk capacitance in the local area of all

devices.

The schematic example focuses on functional connections and is not

configuration specific. Refer to the pin description and functional

tables in the datasheet to ensure the logic control inputs are properly

set

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

vulnerable to random noise. To achieve optimum jitter performance,

power supply isolation is required. The UFT (IDT8T49N203I)

provides separate power supplies to isolate any high switching noise

from coupling into the internal PLL.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

3.3V

FB1

VDDO

muRata, BLM18BB221SN1

Output Termination Example

output shown (Note 3)

-

LVDS

VDD

C14

C15

C13

0.1uF

10uF

0.1uF

C4

C5

C6

C7

0.1uF

FB2

Zo = Zo_Dif f = 100-ohm

VDD

U1

muRata, BLM18BB221SN1

+

-

C9

C10

R2 10

C11

C12

R1

C8

0.1uF

10uF

0.1uF

10uF

0.1uF

100

C1

16MHz to 40 MHz

27

26

28

X1

12pF

Q0

5pF

OE0

OE1

(Note 1)

OE0

1

2

VDDO

C2

XTAL_I N

24

23

22

XTAL_OU T

Q1

5pF

(Note 1)

CLK_SEL

4

5

R17

125

R4

(Note 2)

(Note 1)

CLK_SEL

CLK0

OE1

CLK0

6

30

31

37

38

39

40

LOCK_IND

125

CLK0

LOCK_IND

9

CLK_ACTIVE

HOLDOVER

CLKBAD

CLK1BAD

XTALBAD

Zo = 50-ohm

Input Termination

UFT

CLK1

CLK_ACTIVE

HOLDOVER

CLK0BAD

+

-

10

R5

Example

- LVDS input

CLK1

(Note 1)

PLL_BYPASS

12

18

17

15

14

16

shown (Note 3)

100

(Note 2)

PLL_BYPASS

S_A0

CLK1BAD

S_A0

(Note 1)

XTALBAD

nCLK0

S_A1

(Note 1)

S_A1

34

33

SCLK

R6

84

R7

84

3-pole loop filter

SCLK

LF1

LF0

SDATA

CONFIG

VDD

CONFIG

(Note 1)

(Note 2)

C3

0.001uF

R9

R10

125

R3

Output Termination Example

output shown (Note 3)

-

LVPECL

125

R11

220K

Rs

R12

CLK1

4.7K

470K

Input Termination

Cp

Example

- LVPECL

nCLK1

Cs

input shown (Note 3)

VDD

0.001uF

1uF

R14

84

R15

84

Logic Input Pin Examples

Notes

Note 1: CE0, OE1, CLK_SEL, PLL_BYPASS, S_A0 and S_A1 are digital control inputs. If

external pull-up/down needed, see "Logic Input Pin Examples" shown at left. Please note

that OE0 and OE1 are internally pulled up so no external pull-ups are required to enable

them.

VDD

2-pole loop filter - (optional)

Set Logic

Input to '1'

Set Logic

Input to '0'

LF1

LF0

RU1

RU2

1K

Not Installed

Note 2: CLK_SEL, PLL_BYPASS and CONFIG are internally pulled down. No external

compononents required to select default condition.

To Logic

Input pins

Rs

470K

Note 3: Other configurations are supported. Please contact IDT for details.

Cp

Cs

RD1

Not Installed

RD2

1K

0.001uF

1uF

Figure 11. IDT8T49N203I Application Schematic

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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IDT8T49N203I Data Sheet

FemtoClock® NG Universal Frequency Translator

LVPECL Power Considerations

This section provides information on power dissipation and junction temperature for the IDT8T49N203I.

Equations and example calculations are also provided.

1. Power Dissipation.

The total power dissipation for the IDT8T49N203I is the sum of the core power plus the power dissipated in the load(s).

The following is the power dissipation for V_CC= 3.3V + 5ꢀ = 3.465V, which gives worst case results.

NOTE: Please refer to Section 3 for details on calculating power dissipated in the load.

•

Power (core)_MAX= V_{CC_MAX}* I_{EE_MAX}= 3.465V * 332mA = 1150.4W

Power (outputs)_MAX= 33.2mW/Loaded Output pair

If all outputs are loaded, the total power is 2 * 33.2mW = 66.4mW

Total Power__MAX(3.465V, with all outputs switching) = 1150.4mW + 66.4mW = 1216.8mW

2. Junction Temperature.

Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The

maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond

wire and bond pad temperature remains below 125°C.

The equation for Tj is as follows: Tj = θ_JA* Pd_total + T_A

Tj = Junction Temperature

θ_JA= Junction-to-Ambient Thermal Resistance

Pd_total = Total Device Power Dissipation (example calculation is in section 1 above)

T_A= Ambient Temperature

In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance θ_JAmust be used. Assuming no air flow and

a multi-layer board, the appropriate value is 32.4°C/W per Table 9 below.

Therefore, Tj for an ambient temperature of 85°C with all outputs switching is:

85°C + 1.127W * 32.4°C/W = 124.4°C. This is below the limit of 125°C.

This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of

board (multi-layer).

Table 9. Thermal Resistance θ_JAfor 40 Lead VFQFN, Forced Convection

θ_JAby Velocity

Meters per Second

0

1

2.5

Multi-Layer PCB, JEDEC Standard Test Boards

32.4°C/W

25.7°C/W

23.4°C/W

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3. Calculations and Equations.

The purpose of this section is to calculate the power dissipation for the LVPECL output pairs.

LVPECL output driver circuit and termination are shown in Figure 12.

V_CCO

Q1

V_OUT

RL

50Ω

V_CCO- 2V

Figure 12. LVPECL Driver Circuit and Termination

To calculate worst case power dissipation into the load, use the following equations which assume a 50Ω load, and a termination voltage of

V_CCO– 2V.

•

For logic high, V_OUT= V_{OH_MAX}= V_{CCO_MAX}– 0.7V

(V_{CCO_MAX}– V_{OH_MAX}) = 0.7V

For logic low, V_OUT= V_{OL_MAX}= V_{CCO_MAX}– 1.5V

(V_{CCO_MAX}– V_{OL_MAX}) = 1.5V

Pd_H is power dissipation when the output drives high.

Pd_L is the power dissipation when the output drives low.

Pd_H = [(V_{OH_MAX}– (V_{CCO_MAX}– 2V))/R_L] * (V_{CCO_MAX}– V_{OH_MAX}) = [(2V – (V_{CCO_MAX}– V_{OH_MAX}))/R_L] * (V_{CCO_MAX}– V_{OH_MAX}) =

[(2V – 0.7V)/50Ω] * 0.7V = 18.2mW

Pd_L = [(V_{OL_MAX}– (V_{CCO_MAX}– 2V))/R_L] * (V_{CCO_MAX}– V_{OL_MAX}) = [(2V – (V_{CCO_MAX}– V_{OL_MAX}))/R_L]* (V_{CCO_MAX}– V_{OL_MAX}) =

[(2V – 1.5V)/50Ω] * 1.5V = 15mW

Total Power Dissipation per output pair = Pd_H + Pd_L = 33.2mW

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LVDS Power Considerations

This section provides information on power dissipation and junction temperature for the IDT8T49N203I.

Equations and example calculations are also provided.

1. Power Dissipation.

The total power dissipation for the IDT8T49N203I is the sum of the core power plus the power dissipated in the load(s).

The following is the power dissipation for V_CC= 3.3V + 5ꢀ = 3.465V, which gives worst case results.

NOTE: Please refer to Section 3 for details on calculating power dissipated in the load.

•

Power (core)_MAX= V_{CC_MAX}* (I_{CC_MAX}+ I_{CCA_MAX}) = 3.465V * (284mA + 30mA) = 1088.01mW

Power (outputs)_MAX= V_{CCO_MAX}* I_{CCO_MAX}= 3.465V * 40mA = 138.6mW

Total Power__MAX= 1088.01mW + 138.6mW = 1226.61mW

2. Junction Temperature.

Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The

maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond

wire and bond pad temperature remains below 125°C.

The equation for Tj is as follows: Tj = θ_JA* Pd_total + T_A

Tj = Junction Temperature

θ_JA= Junction-to-Ambient Thermal Resistance

Pd_total = Total Device Power Dissipation (example calculation is in section 1 above)

T_A= Ambient Temperature

In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance θ_JAmust be used. Assuming no air flow and

a multi-layer board, the appropriate value is 32.4°C/W per Table 10 below.

Therefore, Tj for an ambient temperature of 85°C with all outputs switching is:

85°C + 1.227W * 32.4°C/W = 124.8°C. This is below the limit of 125°C.

This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of

board (multi-layer).

Table 10. Thermal Resistance θ_JAfor 40 Lead VFQFN, Forced Convection

θ_JAby Velocity

Meters per Second

0

1

2.5

Multi-Layer PCB, JEDEC Standard Test Boards

32.4°C/W

25.7°C/W

23.4°C/W

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Reliability Information

Table 11. θ_JAvs. Air Flow Table for a 40 Lead VFQFN

θ_JAvs. Air Flow

Meters per Second

0

1

2.5

Multi-Layer PCB, JEDEC Standard Test Boards

32.4°C/W

25.7°C/W

23.4°C/W

Transistor Count

The transistor count for IDT8T49N203I is: 50,917

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40 Lead VFQFN Package Outline and Package Dimensions

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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IDT8T49N203I Data Sheet

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40 Lead VFQFN Package Outline and Package Dimensions, continued

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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IDT8T49N203I Data Sheet

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Ordering Information

Table 12. Ordering Information

Part/Order Number

Marking

Package

“Lead-Free” 40 Lead VFQFN

Shipping Packaging

Tray

Temperature

-40°C to +85°C

8T49N203A-dddNLGI

8T49N203A-dddNLGI8

IDT8T49N203A-dddNLGI

Tape & Reel

NOTE: For the specific -ddd order codes, refer to FemtoClock NG Universal Frequency Translator Ordering Product Information document.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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Revision History Sheet

Rev

Table

T12

T8

Page

38

Description of Change

Date

A

5/29/2012

Ordering Information Table - deleted quantity from tape & reel.

17

Per Errata #NEN-12-02, AC Characteristics Table - corrected fourth row test condition

of RMS Phase Jitter LBW Mode from f_IN- 25MHz to f_IN- 19.44MHz.

B

C

8/10/2012

10/9/2012

T5A - T5E

13 - 14

34

Per Errata #NEN-12-07, Power Supply Tables - changed V_CCAmin. specs and I_CCA

max specs.

LVDS Power Considerations - updated calculations to correspond to I_CCAspec.

IDT8T49N203ANLGI REVISION C OCTOBER 9, 2012

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IDT8T49N203I Data Sheet

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We’ve Got Your Timing Solution

6024 Silver Creek Valley Road Sales

Technical Support

800-345-7015 (inside USA)

netcom@idt.com

San Jose, California 95138

+408-284-8200 (outside USA) +480-763-2056

Fax: 408-284-2775

www.IDT.com/go/contactIDT

DISCLAIMER Integrated Device Technology, Inc. (IDT) and its subsidiaries reserve the right to modify the products and/or specifications described herein at any time and at IDT’s sole discretion. All information in this document,

including descriptions of product features and performance, is subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the independent state and are not

guaranteed to perform the same way when installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the

suitability of IDT’s products for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This document is presented only as a guide and does not convey any

license under intellectual property rights of IDT or any third parties.

IDT’s products are not intended for use in applications involving extreme environmental conditons or in life support systems or similar devices where the failure or malfunction of an IDT product can be reasonably expected to signif-

icantly affect the health or safety of users. Anyone using an IDT product in such a manner does so at their own risk, absent an express, written agreement by IDT.

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party owners.

厂商	型号	描述	页数
HUTSON	8T44A	[ TRIAC, 400V V(DRM), 4A I(T)RMS, TO-202, ]	2 页
TECCOR	8T44HA	晶闸管产品目录[ Thyristor Product Catalog ]	223 页
HUTSON	8T44HA	[ TRIAC, 400V V(DRM), 4A I(T)RMS, TO-202, ]	2 页
TECCOR	8T44SH	晶闸管产品目录[ Thyristor Product Catalog ]	223 页
HUTSON	8T44SH	[ 4 Quadrant Logic Level TRIAC, 400V V(DRM), 4A I(T)RMS, TO-202, ]	2 页
HUTSON	8T44TH	[ TRIAC, 400V V(DRM), 4A I(T)RMS, TO-202, ]	2 页
HUTSON	8T46HA	[ TRIAC, 400V V(DRM), 6A I(T)RMS, TO-202, ]	2 页
HUTSON	8T46SH	[ 4 Quadrant Logic Level TRIAC, 400V V(DRM), 6A I(T)RMS, TO-202 ]	2 页
HUTSON	8T46TH	[ TRIAC, 400V V(DRM), 6A I(T)RMS, TO-202, ]	2 页
VISHAY	8T4702A5	[ RESISTOR, TEMPERATURE DEPENDENT, NTC, 47000 ohm, CHASSIS MOUNT, RADIAL LEADED ]	4 页