MPC9448AC IDT, Integrated Device Technology Inc, MPC9448AC Datasheet - Page 7

MPC9448AC

Manufacturer Part Number

MPC9448AC

Description

IC CLK FAN BUFF MUX 1:12 32LQFP

Manufacturer

IDT, Integrated Device Technology Inc

Type

Fanout Buffer (Distribution), Multiplexerr

Datasheet

1.MPC9448FA.pdf (12 pages)

Specifications of MPC9448AC

Number Of Circuits

Ratio - Input:output

1:12

Differential - Input:output

Yes/No

Input

LVCMOS, LVPECL

Output

LVCMOS

Frequency - Max

350MHz

Voltage - Supply

2.375 V ~ 3.465 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

32-LQFP

Frequency-max

350MHz

Number Of Clock Inputs

Output Frequency

350MHz

Output Logic Level

LVCMOS

Operating Supply Voltage (min)

2.375V

Operating Supply Voltage (typ)

2.5/3.3V

Operating Supply Voltage (max)

3.465V

Package Type

TQFP

Operating Temp Range

-40C to 85C

Operating Temperature Classification

Industrial

Signal Type

LVCMOS/LVPECL

Mounting

Surface Mount

Pin Count

Quiescent Current

2mA

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

800-2011
MPC9448ACIDT

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IDT™ / ICS™ LVCMOS 1:12 CLOCK FANOUT BUFFER

MPC9448

3.3V/2.5V LVCMOS 1:12 CLOCK FANOUT BUFFER

cause any false clock triggering; however, designers may be

uncomfortable with unwanted reflections on the line. To better

match the impedances when driving multiple lines, the

situation in

terminating resistors are reduced such that when the parallel

combination is added to the output buffer impedance, the line

impedance is perfectly matched.

Power Consumption of the MPC9448 and

Thermal Management

entire operating frequency range up to 350 MHz. The

MPC9448 power consumption, and the associated long-term

reliability, may decrease the maximum frequency limit,

depending on operating conditions such as clock frequency,

supply voltage, output loading, ambient temperature, vertical

convection and thermal conductivity of package and board.

This section describes the impact of these parameters on the

junction temperature and gives a guideline to estimate the

MPC9448 die junction temperature and the associated

device reliability. For a complete analysis of power

consumption as a function of operating conditions and

associated long term device reliability, please refer to the

Freescale application note AN1545. According the AN1545,

the long-term device reliability is a function of the die junction

temperature:

Since this step is well above the threshold region, it will not

The MPC9448 AC specification is guaranteed for the

TOT

Figure 6. Optimized Dual Line Termination

= V

MPC9448

Output

17Ω

Buffer

Figure 6

17Ω + 16Ω || 16Ω = 50Ω || 50Ω

[

CCQ

should be used. In this case, the series

+ V

25Ω = 25Ω

= 16Ω

· f

CLOCK

CLOCK,MAX =

TOT

= 50Ω

(

N · C

[

CCQ

+ V

· N · V

= T

· f

CLOCK

)

]

+ P

[

TOT

[

(

Table 9. Die Junction Temperature and MTFB

junction temperature and impact the device reliability

(MTBF). According to the system-defined tolerable MTBF,

the die junction temperature of the MPC9448 needs to be

controlled, and the thermal impedance of the board/package

should be optimized. The power dissipated in the MPC9448

is represented in equation 1.

MPC9448, C

output.

load, and N is the number of active outputs (N is always 12 in

case of the MPC9448). The MPC9448 supports driving

transmission lines to maintain high signal integrity and tight

timing parameters. Any transmission line will hide the lumped

capacitive load at the end of the board trace, therefore,

is zero for controlled transmission line systems and can be

eliminated from equation 1. Using parallel termination output,

termination results in equation 2 for power dissipation.

parallel or thevenin termination. V

function of the output termination technique, and DC

clock signal duty cycle. If transmission lines are used,

zero in equation 2 and can be eliminated. In general, the use

of controlled transmission line techniques eliminates the

impact of the lumped capacitive loads at the end lines and

greatly reduces the power dissipation of the device.

Equation 3 describes the die junction temperature T

function of the power consumption.

(junction to ambient), and T

According to

to estimate the long-term device reliability. Further, combining

equation 1 and equation 2 results in a maximum operating

frequency for the MPC9448 in a series terminated

transmission line system, equation 4.

N · C

· R

j,MAX

Junction Temperature (°C)

Increased power consumption will increase the die

Where I

In equation 2, P stands for the number of outputs with a

Where R

thja

· I

thja

– T

(Μ)Σ

· (V

CCQ

thja

100

110

120

130

Figure

– (I

is the thermal impedance of the package

is the static current consumption of the

)

is the power dissipation capacitance per

represents the external capacitive output

– V

]

CCQ

· V

9, the junction temperature can be used

· V

) + (1 – DC

)

is the ambient temperature.

]

MPC9448

) · I

, I

MTBF (Years)

, V

· V

20.4

9.1

4.2

2.0

REV 6 JULY 11, 2006

and I

]

Equation 1

Equation 2

Equation 3

Equation 4

as a

is the

are a

MPC9448AC IDT, Integrated Device Technology Inc, MPC9448AC Datasheet - Page 7

MPC9448AC

Specifications of MPC9448AC

Available stocks

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