Motorola MC10E416FN, MC10E416FNR2, MC100E416FN, MC100E416FNR2 Datasheet

LOGIC DIAGRAM

D

3

D

2

D

2

V

EE

V

BB
D

0

D

0

26

27

28

2

3

4

25 24 23 22 21 20 19

18

17

16

15

14

13

12

115 6 7 8 9 10

D3D

4

D4V

CCO

Q4Q4V

CCO

Q

3

Q

3

V

CC

Q

2

Q

2

V

CCO

Q

1

D1D1V

CCOQ0

Q0V

CCOQ1

D

0

D

0

D

1

D

1

D

2

D

2

D

3

D

3

D

4

D

4

Q

0

Q

0

Q

1

Q

1

Q

2

Q

2

Q

3

Q

3

Q

4

Q

4

V

BB

1

Pinout: 28-Lead PLCC (Top View)

* All VCC and V

CCO

pins are tied together on the die.



SEMICONDUCTOR TECHNICAL DATA

2–1

REV 2

 Motorola, Inc. 1996

12/93

  


The MC10E416/100E416 is a 5-bit differential line receiving device.
The 2.0GHz of bandwidth provided by the high frequency outputs makes
the device ideal for buffering of very high speed oscillators.

A VBB pin is available to AC couple an input signal to the device. More
information on AC coupling can be found in the design handbook section
of this data book.

The design incorporates two stages of gain, internal to the device,
making it an excellent choice for use in high bandwidth amplifier
applications.

The differential inputs have internal clamp structures which will force
the Q output of a gate in an open input condition to go to a LOW state.
Thus, inputs of unused gates can be left open and will not affect the
operation of the rest of the device. Note that the input clamp will take
affect only if both inputs fall 2.5V below VCC.

• Differential D and Q; V

BB

available

• 600ps Max. Propagation Delay

• High Frequency Outputs

• 2 Stages of Gain

• Extended 100E V

EE

Range of – 4.2V to – 5.46V

• Internal 75kΩ Input Pulldown Resistors

PIN NAMES

Pin Function

D[0:4], D[0:4] Differential Data Inputs
Q[0:4], Q[0:4] Differential Data Outputs





QUINT DIFFERENTIAL

LINE RECEIVER

FN SUFFIX

PLASTIC PACKAGE

CASE 776-02

MC10E416 MC100E416

MOTOROLA ECLinPS and ECLinPS Lite

DL140 — Rev 4

2–2

DC CHARACTERISTICS (VEE = VEE(min) to VEE(max); VCC = V

CCO

= GND)

0°C 25°C 85°C

Symbol Characteristic min typ max min typ max min typ max Unit Condition

V

BB

Output Reference Voltage V

10E –1.38 –1.27 –1.35 –1.25 –1.31 –1.19
100E –1.38 –1.26 –1.38 –1.26 –1.38 –1.26

I

IH

Input HIGH Current 150 150 150 µA

I

EE

Power Supply Current mA

10E 135 162 135 162 135 162

100E 135 162 135 162 155 186
VPP(DC) Input Sensitivity 50 50 50 mV 1
V

CMR

Common Mode Range –1.5 0 –1.5 0 –1.5 0 V 2

1. Differential input voltage required to obtain a full ECL swing on the outputs.

2. V

CMR

is referenced to the most positive side of the differential input signal. Normal operation is obtained when the input signal are within the

V

CMR

range and the input swing is greater than VPP

MIN

and < 1.0V

AC CHARACTERISTICS (VEE = VEE(min) to VEE(max); VCC = V

CCO

= GND)

0°C 25°C 85°C

Symbol Characteristic min typ max min typ max min typ max Unit Condition

t

PLH

Propagation Delay to Output ps

t

PHL

d(Diff) 250 350 500 250 350 500 250 350 500

D(SE) 200 350 550 200 350 550 200 350 550
t

SKEW

Within-Device Skew 50 50 50 ps 1

t

SKEW

Duty Cycle Skew

t

PLH-tPHL

±10 ±10 ±10 ps 2
VPP(AC) Minimum Input Swing 150 150 150 mV 3
t

r

Rise/Fall Time

t

f

20 - 80% 100 200 350 100 200 350 100 200 350 ps

1. Within-device skew is defined as identical transitions on similar paths through a device.

2. Duty cycle skew defined only for differential operation when the delays are measured from the cross point of the inputs to the cross point of
the outputs.

3. Minimum input swing for which AC parameters are guaranteed.