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MC100ES6220AER2

P1-P3P4-P6P7-P9
Advanced Clock Drivers Devices
4 Freescale Semiconductor
MC100ES6220
Table 4. PECL DC Characteristics (V
CC
= 2.5 V ± 5% or V
CC
= 3.3 V ± 5%, V
EE
= GND, T
J
= 0°C to +110°C)
Symbol Characteristics Min Typ Max Unit Condition
Clock Input Pair CLKA, CLKA
, CLKB, CLKB (PECL differential signals)
V
PP
Differential Input Voltage
(1)
1. V
PP
(DC) is the minimum differential input voltage swing required to maintain device functionality.
0.1 1.3 V Differential operation
V
CMR
Differential Cross Point Voltage
(2)
2. V
CMR
(DC) is the crosspoint of the differential input signal. Functional operation is obtained when the crosspoint is within the V
CMR
(DC)
range and the input swing lies within the V
PP
(DC) specification.
1.0 V
CC
– 0.3 V Differential operation
I
IN
Input Current
(1)
±150 µAV
IN
= V
IL
or V
IN
= V
IH
Clock Inputs (PECL single ended signals)
V
IH
Input Voltage High V
CC
– 1.165 V
CC
– 0.880 V
V
IL
Input Voltage Low V
CC
– 1.810 V
CC
– 1.475 V
I
IN
Input Current
(3)
3. Input have internal pullup/pulldown resistors which affect the input current.
±150 µAV
IN
= V
IL
or V
IN
= V
IH
PECL Clock Outputs (QA0-A9, QA0-A9, QB0-B9, QB0-B9)
V
OH
Output High Voltage V
CC
– 1.1 V
CC
– 1.005 V
CC
– 0.7 V I
OH
= –30 mA
(4)
4. Termination 50 to V
TT
.
V
OL
Output Low Voltage V
CC
– 1.9 V
CC
– 1.705 V
CC
– 1.4 V I
OL
= –5 mA
(4)
Supply current and V
BB
I
EE
(5)
5. I
CC
calculation: I
CC
= (number of differential output used) x (I
OH
+ I
OL
) + I
EE
I
CC
= (number of differential output used) x (V
OH
– V
TT
) ÷ R
load
+ (V
OL
– V
TT
) ÷R
load
+ I
EE
.
Maximum Quiescent Supply Current without
Output Termination Current
80 130 mA V
EE
pins
V
BB
Output Reference Voltage V
CC
– 1.42 V
CC
– 1.20 V I
BB
= 0.3 mA
Table 5. ECL DC Characteristics (V
EE
= –2.5 V ± 5% or V
EE
= –3.3 V ± 5%, V
CC
= GND, T
J
= 0°C to +110°C)
Symbol Characteristics Min Typ Max Unit Condition
Clock Input Pair CLKA, CLKA
, CLKB, CLKB (ECL differential signals)
V
PP
Differential Input Voltage
(1)
1. V
PP
(DC) is the minimum differential input voltage swing required to maintain device functionality.
0.1 1.3 V Differential operation
V
CMR
Differential Cross Point Voltage
(2)
2. V
CMR
(DC) is the crosspoint of the differential input signal. Functional operation is obtained when the crosspoint is within the V
CMR
(DC)
range and the input swing lies within the V
PP
(DC) specification.
V
EE
+ 1.0 –0.3 V Differential operation
I
IN
Input Current
(1)
±150 µAV
IN
= V
IL
or V
IN
= V
IH
Clock Inputs (ECL single ended signals)
V
IH
Input Voltage High –1.165 –0.880 V
V
IL
Input Voltage Low –1.810 –1.475 V
I
IN
Input Current
(3)
3. Input have internal pullup/pulldown resistors which affect the input current.
±150 µAV
IN
= V
IL
or V
IN
= V
IH
ECL Clock Outputs (QA0–A9, QA0–A9, QB0–B9, QB0–B9)
V
OH
Output High Voltage –1.1 –1.005 –0.7 V I
OH
= –30 mA
(4)
4. Termination 50 to V
TT
.
V
OL
Output Low Voltage –1.9 –1.705 –1.4 V I
OL
= –5 mA
(4)
Supply Current and V
BB
I
EE
(5)
5. I
CC
calculation: I
CC
= (number of differential output used) x (I
OH
+ I
OL
) + I
EE
I
CC
= (number of differential output used) x (V
OH
– V
TT
) ÷ R
load
+ (V
OL
– V
TT
) ÷ R
load
+ I
EE
.
Maximum Quiescent Supply Current without
Output Termination Current
80 130 mA V
EE
pins
V
BB
Output Reference Voltage –1.42 –1.20 V I
BB
= 0.3 mA
MC100ES6220
Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer NETCOM
IDT™ Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
MC100ES6220
4
Advanced Clock Drivers Devices
Freescale Semiconductor 5
MC100ES6220
Figure 3. MC100ES6220 AC Test Reference
Figure 4. MC100ES6220 AC Reference Measurement Waveform
Table 6. AC Characteristics (ECL: V
EE
= –3.3 V ± 5% or V
EE
= –2.5 V ± 5%, V
CC
= GND) or
(PECL: V
CC
= 3.3 V ± 5% or V
CC
= 2.5 V ± 5%, V
EE
= GND, T
J
= 0°C to +110°C)
(1)
1. AC characteristics apply for parallel output termination of 50 to V
TT
.
Symbol Characteristics Min Typ Max Unit Condition
Clock Input Pair CLKA, CLKA, CLKB, CLKB (PECL or ECL differential signals)
V
PP
Differential Input Voltage
(2)
(peak-to-peak)
2. V
PP
(AC) is the minimum differential ECL/PECL input voltage swing required to maintain AC characteristics including t
PD
and
device-to-device skew.
0.3 1.3 V
V
CMR
Differential Input Crosspoint Voltage
(3)
PECL
ECL
3. V
CMR
(AC) is the crosspoint of the differential ECL/PECL input signal. Normal AC operation is obtained when the crosspoint is within the
V
CMR
(AC) range and the input swing lies within the V
PP
(AC) specification. Violation of V
CMR
(AC) or V
PP
(AC) impacts the device
propagation delay, device and part-to-part skew.
1.1
V
EE
+ 1.1
V
CC
– 0.3
–0.3
V
V
f
CLK
Input Frequency 0 1000 MHz Differential
PECL/ECL Clock Outputs (QA0-A9, QA0-A9, QB0-B9, QB0-B9
)
t
PD
Propagation Delay CLKx to Qx0-9 285 550 ps Differential
V
O(P-P)
Differential Output Voltage (peak-to-peak) 400 600 mV
t
sk(O)
Output-to-Output Skew 60 130 ps Differential
t
sk(PP)
Output-to-Output Skew (part-to-part) 200 ps Differential
t
JIT(CC)
Output Cycle-to-Cycle Jitter RMS (1σ)1ps
t
SK(P)
DC
O
Output Pulse Skew
(4)
Output Duty Cycle f
REF
< 0.1 GHz
f
REF
< 1.0 GHz
4. Output pulse skew is the absolute difference of the propagation delay times: | t
pLH
– t
pHL
|.
49.65
46.5
50
50
35
50.35
53.5
ps
%
%
DC
REF
= 50%
DC
REF
= 50%
t
r
, t
f
Output Rise/Fall Time 50 350 ps 20% to 80%
Differential Pulse
Generator
Z = 50
R
T
= 50
Z = 50
DUT
MC100ES6220
V
TT
R
T
= 50
Z = 50
V
TT
t
PD
(CLK
N
to Q
X
)
V
CMR
= V
CC
– 1.3 V
V
PP
= 0.8 V
CLK
N
CLK
N
Q
X
Q
X
MC100ES6220
Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer NETCOM
IDT™ Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
MC100ES6220
5
Advanced Clock Drivers Devices
6 Freescale Semiconductor
MC100ES6220
APPLICATIONS INFORMATION
Understanding the Junction Temperature Range of the
MC100ES6220
To make the optimum use of high clock frequency and low
skew capabilities of the MC100ES6220, the MC100ES6220
is specified, characterized and tested for the junction
temperature range of T
J
=0°C to +110°C. Because the exact
thermal performance depends on the PCB type, design,
thermal management and natural or forced air convection,
the junction temperature provides an exact way to correlate
the application specific conditions to the published
performance data of this data sheet. The correlation of the
junction temperature range to the application ambient
temperature range and vice versa can be done by
calculation:
T
J
= T
A
+ R
thja
P
tot
Assuming a thermal resistance (junction to ambient) of
17°C/W (2s2p board, 200 ft/min airflow, see Table 8) and a
typical power consumption of 1049 mW (all outputs
terminated 50 ohms to V
TT
, V
CC
= 3.3 V, frequency
independent), the junction temperature of the MC100ES6220
is approximately T
A
+18°C, and the minimum ambient
temperature in this example case calculates to
18°C (the
maximum ambient temperature is 92°C. See Table 7).
Exceeding the minimum junction temperature specification of
the MC100ES6220 does not have a significant impact on the
device functionality. However, the continuous use the
MC100ES6220 at high ambient temperatures requires
thermal management to not exceed the specified maximum
junction temperature. Please see the application note
AN1545 for a power consumption calculation guideline.
Maintaining Lowest Device Skew
The MC100ES6220 guarantees low output-to-output bank
skew of 100 ps and a part-to-part skew of max. 200 ps. To
ensure low skew clock signals in the application, both outputs
of any differential output pair need to be terminated
identically, even if only one output is used. When fewer than
all nine output pairs are used, identical termination of all
output pairs within the output bank is recommended. This will
reduce the device power consumption while maintaining
minimum output skew.
Power Supply Bypassing
The MC100ES6220 is a mixed analog/digital product. The
differential architecture of the MC100ES6220 supports low
noise signal operation at high frequencies. In order to
maintain its superior signal quality, all V
CC
pins should be
bypassed by high-frequency ceramic capacitors connected
to GND. If the spectral frequencies of the internally generated
switching noise on the supply pins cross the series resonant
point of an individual bypass capacitor, its overall impedance
begins to look inductive and thus increases with increasing
frequency. The parallel capacitor combination shown ensures
that a low impedance path to ground exists for frequencies
well above the noise bandwidth.
Figure 5. V
CC
Power Supply Bypass
Table 7. Ambient Temperature Ranges (P
tot
= 1049 mW)
R
thja
(2s2p board)
T
A, min
(1)
1. The MC100ES6220 device function is guaranteed from
T
A
= –40°C to T
J
= 110°C.
T
A, max
Natural convection 20°C/W –21°C89°C
100 ft/min 18°C/W –19°C91°C
200 ft/min 17°C/W –18°C92°C
400 ft/min 16°C/W –17°C93°C
800 ft/min 15°C/W –16°C94°C
V
CC
MC100ES6220
V
CC
33...100 nF 0.1 nF
MC100ES6220
Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer NETCOM
IDT™ Low Voltage Dual 1:10 Differential ECL/PECL Clock Fanout Buffer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
MC100ES6220
6
P1-P3P4-P6P7-P9

MC100ES6220AER2

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Manufacturer:
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Description:
Clock Buffer FSL Dual 1-10 Diff LVPECL Fanout Buffer
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