ON NB6L239MNEVB Nb6l239mnevb evaluation board users manual Datasheet

NB6L239MNEVB
NB6L239MNEVB Evaluation
Board User's Manual
http://onsemi.com
EVAL BOARD USER’S MANUAL
Description
Board Features
The NB6L239 Evaluation Board was designed to provide
a flexible and convenient platform to quickly evaluate,
characterize and verify the performance and operation of the
NB6L239. This user’s manual provides detailed
information on board contents, layout and its use. It should
be used in conjunction with the NB6L239 data sheet:
(www.onsemi.com).
The NB6L239 is a differential Receiver to differential
LVPECL Clock Divider. The board features Output Enable
control of the Outputs.
• Accommodates the electrical characterization of the
•
•
•
•
•
NB6L239
Selectable Jumper for the VT pin, minimizing cabling
CLK/CLK input and QA/QA and QB/QB output pins
are accessed via SMA connectors
MR, EN and Clock Divide Select pins are accessed via
SMA Connectors or by the Logic Switches
Convenient and compact board layout
2.5 V, 3.3 V Power Supply Operating Range
Figure 1. Evaluation Board
© Semiconductor Components Industries, LLC, 2012
February, 2012 − Rev. 1
1
Publication Order Number:
EVBUM2081/D
NB6L239MNEVB
PROCEDURE
Lab Setup and Measurement Procedure
Dual Power Supplies
Equipment Used
•
•
•
•
•
Agilent Signal Generator #8133A
Tektronix TDS8000 Oscilloscope
Agilent #6624A DC Power Supply
Digital Voltmeter
Matched High−Speed Cables with SMA Connectors
+2.0 V
+
VCC
Power Supply Connections
The NB6L239 has a positive supply pin, VCC, and a
negative supply pin, VEE. SMAGND = VTT = VCC – 2.0 V
is the termination supply for the LVPECL outputs, only.
Power supply terminals VCC, VEE and SMAGND are
provided. The SMAGND terminal is for the isolated SMA
connector GROUND plane, and is not to be confused with
a device VEE pin. Since SMAGND = VTT = VCC – 2.0 V, is
the termination supply for the LVPECL outputs, by
offsetting VCC by +2.0 V yields VTT = 0 V or Ground. A
“split” or dual power supply technique can be used to take
advantage of terminating the PECL outputs into 50 W to
Ground of an oscilloscope or a frequency counter.
(see AND8020/D
for
more
information
on
terminating ECL).
Power Supply
Connector
Color
“Spilt” Power Supply
VCC
RED
VCC = +2.0 V
−
BLACK −
SMAGND
VTT = VCC – 2 V = 0 V
VEE – 239
YELLOW
VEE = −1.3 V (or –0.5 V)
VTT
+
−
VEE
+3.3 V
Figure 2. “Split” or Dual Power Supply Connections
NB6L239
To monitor the QA/QA and QB/QB outputs on an
oscilloscope, the power supply needs to be DC offset:
1. Connect a “split” power supply to the evaluation
board. (Figure 1)
Connect VCC to +2.0 V
Connect SMAGND to 0 V
Connect VEE to −1.3 V for 3.3 V operation; or
–0.5 V for 2.5 V operation
2. Ensure the oscilloscope is triggered properly and
has 50 W termination to ground. The board does
not provide 50 W source termination resistors.
Trigger the oscilloscope from trigger output of
signal generator.
3. Connect the LVPECL QA/QA and QB/QB outputs
to the oscilloscope with matched cables. The
outputs are terminated with 50 W to VTT
(VCC – 2.0 V) = 0 V = Ground internal to
the oscilloscope.
Table 1. POWER SUPPLY CONFIGURATIONS
Device
Pin
+1.3 V
−
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2
NB6L239MNEVB
MR
SELA0 SELA1
VCC
SMAGND VEE/GND
Signal Generator
QA
CLK
QA
CLK
QB
VBBAC
QB
OUT
OUT
Digital Oscilloscope
or Frequency Counter
50 W
50 W
50 W
50 W
Trigger Out
EN
SELB0
SELB1
Trigger
50 W
Figure 3. Evaluation Board
Board Layout
a logic LOW owing to the pulldown resistor; a logic LOW
voltage is not forced on the pin. In the HIGH position, the
switch forces the SELXn and EN pin to the positive power
supply rail, a logic HIGH.
The MR device pin has an internal pullup resistor. When
the MR switch is in the logic HIGH position, the input pin
“floats” to a logic HIGH owing to the pullup resistor; a logic
HIGH voltage is not forced on the pin. In the LOW position,
the switch forces the MR pin to the negative power supply
rail, a logic LOW.
The evaluation board is constructed with Rogers material
with 50 W trace impedances designed to minimize noise,
achieve high bandwidth and minimize crosstalk.
Layer Stack
L1
L2
L3
L4
Signal (top) (Rogers)
SMA Ground
VCC and VEE (positive and negative power supply)
Signal (bottom)
Control and Select Pins
VBB = VBBAC
The Control / Select pins, MR, SELXn and EN, can be
accessed via the appropriate SMA connector. These pins can
also be manually controlled by using the H/L switch. When
using the switch, the SMA connector should be left open.
When using the SMA connector, the switch must be in the
“OPEN” position.
The SELXn and EN device pins have internal pulldown
resistors. The NB6L239 evaluation board was designed to
take advantage of this attribute. When the SELXn and EN
switch is in the logic LOW position, the input pin “floats” to
VBB labeled on the board is actually VBBAC per the data
sheet.
VT
The VT pin can be set to VCC, VEE (239) GND (239S),
VBB or SMAGND by using a jumper.
VEE / GND
VEE is the negative supply for the NB6L239. GND is the
negative supply for NB6N239S.
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3
NB6L239MNEVB
Table 2. PIN DESCRIPTION (refer to data sheet, NB6L239/D)
Pin #
16−QFN
Pin Name
1
VT
2
CLK
Input
LVPECL, CML, LVDS,
HSTL
Noninverted Differential CLOCK Input.
3
CLK
Input
LVPECL, CML, LVDS,
HSTL
Inverted Differential CLOCK Input.
4
VBBAC
Output
Reference Voltage
5
EN
Input
L
LVCMOS/LVTTL Input
Synchronous Output Enable
6
SELB0
Input
L
LVCMOS/LVTTL Input
Clock Divide Select Pin
7
SELB1
Input
L
LVCMOS/LVTTL Input
Clock Divide Select Pin
8
VEE
Negative Power
Supply
9
QB
Output
LVPECL
Inverted Differential Output. Typically
terminated with 50 W resistor to VTT.
10
QB
Output
LVPECL
Noninverted Differential Output. Typically
terminated with 50 W resistor to VTT.
11
QA
Output
LVPECL
Inverted Differential Output. Typically
terminated with 50 W resistor to VTT.
12
QA
Output
LVPECL
Noninverted Differential Output. Typically
terminated with 50 W resistor to VTT.
13
VCC
Positive Power
Supply
14
SELA1
Input
L
LVCMOS/LVTTL
Clock Divide Select Pin
15
SELA0
Input
L
LVCMOS/LVTTL Input
Clock Divide Select Pin
16
MR
Input
H
LVCMOS/LVTTL Input
Master Reset Asynchronous, Default Open
High, Asserted LOW
EP
Negative Power
Supply (opt)
I/O
Open Pin
Default
Type
Function
Internal 100 W Center
Output Voltage Reference for Capacitor
Coupled Inputs, Only.
Negative Supply Voltage
Positive Power Supply
The Exposed Pad on the QFN−16 package
bottom is thermally connected to the die for
improved heat transfer out of package. The
pad is not electrically connected to the die, but
is recommended to be electrically and
thermally connected to VEE on the PC board.
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4
NB6L239MNEVB
EVALUATION BOARD APPLICATION INFORMATION
Table 3. EVALUATION BOARD BILL OF MATERIALS
Component
Description
Qty
Connector
Rosenberger SMA #32K243−40ME3
6
Capacitor
22 mF, 10%, KEMET T491D226K016AS, Case C or D
2
Capacitor
0.1 mF, 10%, KEMET C060C104K5RAC
4
Switch
Grayhill #78B02
4
Jumper Header
100 mil, Berg
5
Jumper/Shunt
1
Resistor
1 kW, 0603
6
Banana Jack
Deltron #EF681 150−039 Red
1
Banana Jack
Deltron #EF681 150−040 Black
1
Banana Jack
Deltron #EF681 150−043 Yellow
1
Stand−offs with Screws
Optional
4
NB6L239 or NB6N239S
QFN−16 Part Mounted on Board
1
QFN−16 Socket
Optional, M&M #50−000−00350
1
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5
NB6L239MNEVB
S
M
A
S
M
A
S
M
A
H
L
VEE
VCC
VCC
Switch MR SELA0 SELA1 V
CC
16
VTT
H
L
15
14
13
VBBAC
VT
VEE/GND
CLK
SMA
12
2
11
TOP VIEW
CLK
SMA
SMA
1
VBBAC
3
10
4
9
5
EN
6
7
Switch
S
M
A
QA
QB
QB
SMA
SMA
SMA
SMA
8
SELB0 SELB1 VEE
H
L
VEE
QA
S
M
A
H
L
VEE − 239
GND − 239S
S
M
A
Switch
H = VCC
L = VEE/GND
Rosenberger connectors with matched trace launches
Switch for MR
Normally open switch for EN
CLK & CLK traces – equal length
All Q Output traces – equal length
“Side−mount” banana jacks for power supplies (can be located on backside of board)
VT pin has a “jumper capability to VCC, VEE / GND, VTT (SMAGND), or VBBAC
Figure 4. Evaluation Demo Board
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