NBSG86A [ONSEMI]
Evaluation Board Manual; 评估板手册型号: | NBSG86A |
厂家: | ONSEMI |
描述: | Evaluation Board Manual |
文件: | 总20页 (文件大小:112K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
NBSG86ABAEVB
Evaluation Board Manual
for NBSG86A
http://onsemi.com
EVALUATION BOARD MANUAL
DESCRIPTION
This document describes the NBSG86A evaluation board
and the appropriate lab test setups. It should be used in
conjunction with the device data sheet, which includes
specifications and a full description of device operation.
The board is used to evaluate the NBSG86A
GigaComm differential Smart Gate multi-function logic
gate, which can be configured as an AND/NAND,
OR/NOR, XOR/XNOR, or 2:1 MUX. The OLS input of the
NBSG86A is used to program the peak–to–peak output
amplitude between 0 and 800 mV in five discrete steps.
The board is implemented in two layers and provides a
high bandwidth 50 W controlled impedance environment for
higher performance. The first layer or primary trace layer is
5 mils thick Rogers RO6002 material, which is engineered
to have equal electrical length on all signal traces from the
NBSG86A device to the sense output. The second layer is
32 mils thick copper ground plane.
What measurements can you expect to make?
The following measurements can be performed in the
single–ended (Note 1) or differential mode of operation:
• Frequency Performance
• Output Amplitude (V /V
)
OL
OH
• Output Rise and Fall Time
• Output Skew
• Eye pattern generation
• Jitter
• V
(Input High Common Mode Range)
IHCMR
For standard lab setup and test, a split (dual) power supply
is required enabling the 50 W impedance from the scope to
NOTE:
1. Single- ended measurements can only be made at
- V = 3.3 V using this board setup.
be used as termination of the ECL signals, where V is the
TT
V
CC
EE
system ground (V = 2.0 V, V = V - 2.0 V and V
CC
TT
CC
EE
is -0.5 V or -1.3 V, see Setup 1).
Figure 1. NBSG86A Evaluation Board
Semiconductor Components Industries, LLC, 2003
1
Publication Order Number:
March, 2003 - Rev. 0
NBSG86ABAEVB/D
NBSG86ABAEVB
Setup for Time Domain Measurements
Table 1. Basic Equipment Needed
Description
Power Supply with 2 Outputs
Oscilloscope
Example Equipment (Note 1)
HP6624A
Qty.
1
TDS8000 with 80E01 Sampling Head (Note 2)
HP 8133A, Advantest D3186
1
Differential Signal Generator
1
Matched High Speed Cables with SMA Connectors Storm, Semflex
Power Supply Cables with Clips
8
3 / 4 (Note 3)
1. This equipment was used to obtain the measurements included in this document.
2. The 50 GHz sample module was used in order to obtain accurate and repeatable rise, fall, and jitter measurements.
3. Additional power supply cable with clip is needed when output level select (OLS) tested (see device data sheet).
AND/NAND Function Setup
Oscilloscope
OUT
OUT
V
TT
= 0 V
V
CC
= 2.0 V
V
CC
D1
D1
GND
Signal Generator
SEL
Q
OUT1
OUT1
Channel 1
Channel 2
SEL
Q
Amplitude = 400 mV
Offset = 660 mV
V
EE
OLS
D0
D0
TRIGGER
V
V
= -1.3 V (3.3 V op)
or
= -0.5 V (2.5 V op)
EE
OLS*
V
= 0 V V = 2.0 V
CC
TT
EE
TRIGGER
*See NBSG86A data sheet pg 2.
Figure 2. NBSG86A Board Setup - Time Domain (AND/NAND Function)
Connect Power
Step 1:
1a. Connect the following supplies to the evaluation board via surface mount clips.
Power Supply Summary Table
3.3 V Setup
2.5 V Setup
V
= 2.0 V
= GND
V
= 2.0 V
= GND
CC
CC
V
V
TT
TT
V
EE
= -1.3 V
V
EE
= -0. 5V
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NBSG86ABAEVB
AND/NAND Function Setup (continued)
Connect the Inputs
For Differential Mode (3.3 V and 2.5 V operation)
Step 2:
2a: Connect the differential outputs of the generator to the differential inputs of the device
(D1/D1 and SEL/SEL).
2b: Connect the DO input to V
.
TT
2c: Connect the DO input to V
.
CC
2d: Connect the generator trigger to the oscilloscope trigger.
For Single-Ended Mode (3.3 V operation only)
2a: Connect an AC-coupled output of the generator to the desired differential input of the
device.
2b: Connect the unused differential input of the device to V (GND) through a 50 W resis-
TT
tor.
2c: Connect the DO input to V
.
TT
2d: Connect the DO input to V
.
CC
2e: Connect the generator trigger to the oscilloscope trigger.
All Function Setups
Connect OLS (Output Level Select) to the required voltage to obtain desired output ampli-
tude. Refer to the NBSG86A device data sheet page 2 OLS voltage table.
Setup Input Signal
Step 3:
3a: Set the signal generator amplitude to 400 mV. Note that the signal generator amplitude
can vary from 75 mV to 900 mV to produce a 400 mV DUT output.
3b: Set the signal generator offset to 660 mV (the center of a nominal RSECL output). Note
that the V
(Input High Voltage Common Mode Range) allows the signal generator
IHCMR
offset to vary as long as V is within the V
range. Refer to the device data sheet for
IH
IHCMR
further information.
3c: Set the generator output for a square wave clock signal with a 50% duty cycle, or for a
PRBS data signal.
Connect Output Signals
Step 4:
4a: Connect the outputs of the evaluation board (Q, Q) to the oscilloscope. The
oscilloscope sampling head must have internal 50 W termination to ground.
NOTE: Where a single output is being used, the unconnected output for the pair must be terminated to
V
TT
V
TT
through a 50 W resistor for best operation. Unused pairs may be left unconnected. Since
= 0 V, a standard 50 W SMA termination is recommended.
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NBSG86ABAEVB
OR/NOR Function Setup
V
CC
= 2.0 V V = 0 V
TT
V
TT
= 0 V
GND
V
= 2.0 V
CC
Oscilloscope
D1
D1
V
CC
Signal Generator
SEL
Q
OUT
Channel 1
Channel 2
Amplitude = 400 mV
Offset = 660 mV
OUT
Q
SEL
OUT1
OLS
V
EE
D0
D0
OUT1
OLS*
V
V
= -1.3 V (3.3 V op)
or
= -0.5 V (2.5 V op)
EE
TRIGGER
EE
TRIGGER
*See NBSG86A data sheet pg 2.
Figure 3. NBSG86A Board Setup - Time Domain (OR/NOR Function)
Connect Power
Step 1:
1a: Connect the following supplies to the evaluation board via surface mount clips.
Power Supply Summary Table
2.5 V Setup
3.3 V Setup
V
= 2.0 V
= GND
V
= 2.0 V
= GND
CC
CC
V
V
TT
TT
V
EE
= -1.3 V
V
EE
= -0.5 V
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NBSG86ABAEVB
OR/NOR Function Setup (continued)
Connect the Inputs
For Differential Mode (3.3 V and 2.5 V operation)
Step 2:
2a: Connect the differential outputs of the generator to the differential inputs of the device
(D0/D0 and SEL/SEL).
2a: Connect the D1 input to V
.
TT
2b: Connect the D1 input to V
.
CC
2e: Connect the generator trigger to the oscilloscope trigger.
For Single-Ended Mode (3.3 V operation only)
2a: Connect an AC-coupled output of the generator to the desired differential input of the
device.
2b: Connect the unused differential input of the device to V (GND) through a 50 W resis-
TT
tor.
2c: Connect the D1 input to V
.
TT
2d: Connect the D1 input to V
.
CC
2e: Connect the generator trigger to the oscilloscope trigger.
All Function Setups
Connect OLS (Output Level Select) to the required voltage to obtain desired output
amplitude. Refer to the NBSG86A device data sheet page 2 OLS voltage table.
Setup Input Signal
Step 3:
3a: Set the signal generator amplitude to 400 mV. Note that the signal generator amplitude
can vary from 75 mV to 900 mV to produce a 400 mV DUT output.
3b: Set the signal generator offset to 660 mV (the center of a nominal RSECL output). Note
that the V
(Input High Voltage Common Mode Range) allows the signal generator
IHCMR
offset to vary as long as V is within the V
range. Refer to the device data sheet for
IH
IHCMR
further information.
3c: Set the generator output for a square wave clock signal with a 50% duty cycle, or for a
PRBS data signal.
Connect Output Signals
Step 4:
4a: Connect the outputs of the evaluation board (Q, Q) to the oscilloscope. The oscilloscope
sampling head must have internal 50 W termination to ground.
NOTE: Where a single output is being used, the unconnected output for the pair must be terminated to
V
TT
V
TT
through a 50 W resistor for best operation. Unused pairs may be left unconnected. Since
= 0 V, a standard 50 W SMA termination is recommended.
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NBSG86ABAEVB
XOR/XNOR Function Setup
OUT1
V
TT
= 0 V
V
CC
= 2.0 V
Oscilloscope
OUT1
GND
D1
D1
V
CC
Signal Generator
SEL
Q
OUT
Channel 1
Channel 2
Amplitude = 400 mV
Offset = 660 mV
OUT
SEL
OLS
Q
OUT1
V
EE
D0
D0
OUT1
OLS*
V
V
= -1.3 V (3.3 V op)
or
= -0.5 V (2.5 V op)
EE
TRIGGER
EE
TRIGGER
*See NBSG86A data sheet pg 2.
Figure 4. NBSG86A Board Setup - Time Domain (XOR/XNOR Function)
Connect Power
Step 1:
1a: Connect the following supplies to the evaluation board via surface mount clips.
Power Supply Summary Table
2.5 V Setup
3.3 V Setup
V
= 2.0 V
= GND
V
= 2.0 V
= GND
CC
CC
V
V
TT
TT
V
EE
= -1.3 V
V
EE
= -0.5 V
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NBSG86ABAEVB
XOR/XNOR Function Setup (continued)
Connect the Inputs
For Differential Mode (3.3 V and 2.5 V operation)
Step 2:
2a: Connect the differential outputs of the generator to the differential inputs of the device
(OUT OUT to SEL/SEL; OUT1/OUT1 to DO&D1/D0&D1 respectively).
Step 2e: Connect the generator trigger to the oscilloscope trigger.
For Single-Ended Mode (3.3 V operation only)
2a: Connect an AC-coupled output of the generator to the desired differential input of the
device.
2b: Connect the unused differential input of the device to V (GND) through a
TT
50 W resistor.
2e: Connect the generator trigger to the oscilloscope trigger.
All Function Setups
Connect OLS (Output Level Select) to the required voltage to obtain desired output ampli-
tude. Refer to the NBSG86A device data sheet page 2 OLS voltage table.
Setup Input Signal
Step 3:
3a: Set the signal generator amplitude to 400 mV. Note that the signal generator amplitude
can vary from 75 mV to 900 mV to produce a 400 mV DUT output.
3b: Set the signal generator offset to 660 mV (the center of a nominal RSECL output). Note
that the V
(Input High Voltage Common Mode Range) allows the signal generator
IHCMR
offset to vary as long as V is within the V
range. Refer to the device data sheet for
IH
IHCMR
further information.
3c: Set the generator output for a square wave clock signal with a 50% duty cycle, or for a
PRBS data signal.
Connect Output Signals
Step 4:
4a: Connect the outputs of the evaluation board (Q, Q) to the oscilloscope. The oscilloscope
sampling head must have internal 50 W termination to ground.
NOTE: Where a single output is being used, the unconnected output for the pair must be terminated to
V
TT
V
TT
through a 50 W resistor for best operation. Unused pairs may be left unconnected. Since
= 0 V, a standard 50 W SMA termination is recommended.
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NBSG86ABAEVB
2:1 MUX Function Setup
V
TT
= 0 V
V
CC
= 2.0 V
Oscilloscope
OUT
OUT
D1
D1
GND
V
CC
SEL
Q
V
= 2.0 V
Channel 1
Channel 2
CC
Signal Generator
V
= 0 V
CC
SEL
OLS
Q
Amplitude = 400 mV
Offset = 660 mV
V
EE
D0
D0
TRIGGER
OLS*
V
V
= -1.3 V (3.3 V op)
or
= -0.5 V (2.5 V op)
EE
V
TT
= 0 V V = 2.0 V
CC
EE
TRIGGER
*See NBSG86A data sheet pg 2.
Figure 5. NBSG86A Board Setup - Time Domain (2:1 MUX Function)
Connect Power
Step 1:
1a: Connect the following supplies to the evaluation board via surface mount clips.
Power Supply Summary Table
3.3 V Setup
2.5 V Setup
V
= 2.0 V
= GND
V
= 2.0 V
= GND
= -0.5
CC
CC
V
V
TT
TT
V
EE
= -1.3 V
V
EE
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NBSG86ABAEVB
2:1 MUX Function Setup (continued)
Connect the Inputs
For Differential Mode (3.3 V and 2.5 V operation)
Step 2:
2a: Connect the differential outputs of the generator to the differential inputs of the device
(D1/D1).
2b: Connect the D0 input to V and the D0 input to V
.
TT
CC
2c: Connect the SEL input to V and the SEL input to V
.
TT
CC
2d: Connect the generator trigger to the oscilloscope trigger.
For Single-Ended Mode (3.3 V operation only)
2a: Connect an AC-coupled output of the generator to the desired differential input of the
device.
2b: Connect the unused differential input of the device to V (GND) through a 50 W
TT
resistor.
2c: Connect the D0 input to V and the D0 input to V
.
CC
TT
2d: Connect the SEL input to V and the SEL input to V
.
TT
CC
2e: Connect the generator trigger to the oscilloscope trigger.
All Function Setups
Connect OLS (Output Level Select) to the required voltage to obtain desired output
amplitude. Refer to the NBSG86A device data sheet page 2 OLS voltage table.
Setup Input Signal
Step 3:
3a: Set the signal generator amplitude to 400 mV. Note that the signal generator amplitude
can vary from 75 mV to 900 mV to produce a 400 mV DUT output.
3b: Set the signal generator offset to 660 mV (the center of a nominal RSECL output). Note
that the V
(Input High Voltage Common Mode Range) allows the signal generator
IHCMR
offset to vary as long as V is within the V
range. Refer to the device data sheet for
IH
IHCMR
further information.
3c: Set the generator output for a square wave clock signal with a 50% duty cycle, or for a
PRBS data signal.
Connect Output Signals
Step 4:
4a: Connect the outputs of the evaluation board (Q, Q) to the oscilloscope. The oscilloscope
sampling head must have internal 50 W termination to ground.
NOTE: Where a single output is being used, the unconnected output for the pair must be terminated to
V
TT
V
TT
through a 50 W resistor for best operation. Unused pairs may be left unconnected. Since
= 0 V, a standard 50 W SMA termination is recommended.
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NBSG86ABAEVB
Setup for Frequency Domain Measurements
Table 2. Basic Equipment
Description
Example Equipment (Note 4)
Qty.
1
Power Supply with 2 outputs
HP 6624A
Vector Network Analyzer (VNA)
180° Hybrid Coupler
R&S ZVK (10 MHz to 40 GHz)
Krytar Model #4010180
Picosecond Model #5542-219
Storm, Semflex
1
1
Bias Tee with 50 W Resistor Termination
Matched high speed cables with SMA connectors
Power Supply cables with clips
1
3
3
4. Equipment used to generate example measurements within this document.
Setup
Step 1:
Connect Power
1a: Three power levels must be provided to the board for V , V , and GND via the
CC
EE
surface mount clips. Using the split power supply mode, GND = V = V – 2.0 V.
TT
CC
Power Supply Connections
3.3 V Setup
V
= 2.0 V
= GND
CC
V
TT
V
EE
= -1.3 V
NOTE: For frequency domain measurements, 2.5 V power supply is not recommended because additional
equipment (bias tee, etc.) is needed for proper operation. The input signal has to be properly offset
to meet V
range of the device.
IHCMR
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NBSG86ABAEVB
Setup Test Configurations For Differential Operation
Small Signal Setup
Step 2:
Step 3:
Input Setup
2a: Calibrate VNA from 1.0 GHz to 12 GHz.
2b: Set input level to –35 dBm at the output of the 180° Hybrid coupler (input of the DUT).
Output Setup
3a: Set display to measure S21 and record data.
Large Signal Setup
Step 2:
Step 3:
Input Setup
2a: Calibrate VNA from 1.0 GHz to 12 GHz.
2b: Set input levels to -2.0 dBm (500 mV) at the input of DUT.
Output Setup
3a: Set display to measure S21 and record data.
Rohde & Schwartz
Vector Network Analyzer
PORT 1
PORT 2
GND
50 W
V
TT
= 0 V
V
CC
= 2.0 V
1805 Hybrid
GND
50 W
Coupler
D1
D1
GND
SEL
V
CC
Q
Q
V
CC
= 2.0 V
Bias T
V
= 0 V
TT
SEL
OLS
50 W
GND
V
EE
D0
D0
OLS*
V
EE
= -1.3 V (3.3 V op)
*See NBSG86A data sheet pg 2.
V
TT
= 0 V V = 2.0 V
CC
Figure 6. NBSG86A Board Setup - Frequency Domain (Differential 2:1 MUX Function - D1 Selected)
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NBSG86ABAEVB
Setup Test Configurations For Single-Ended Operation
Single-Ended Mode – Small Signal
Input Setup
Step 2:
Step 3:
2a: Calibrate VNA from 1.0 GHz to 12 GHz.
2b: Set input level to –35 dBm at the input of DUT.
Output Setup
3a: Set display to measure S21 and record data.
Single-Ended Mode – Large Signal
Step 2:
Step 3:
Input Setup
2a: Calibrate VNA from 1.0 GHz to 12 GHz.
2b: Set input levels to +2 dBm (500 mV) at the input of DUT.
Output Setup
3a: Set display to measure S21 and record data.
Rohde & Schwartz
Vector Network Analyzer
PORT 1
PORT 2
GND
50 W
V
TT
= 0 V
V
CC
= 2.0 V
GND
50 W
D1
D1
GND
V
CC
SEL
Q
Q
V
= 2.0 V
Bias T
CC
V
= 0 V
TT
SEL
50 W
GND
OLS
V
EE
D0
D0
OLS*
V
EE
= -1.3 V (3.3 V op)
*See NBSG86A data sheet pg 2.
V
TT
= 0 V V = 2.0 V
CC
Figure 7. NBSG86A Board Setup - Frequency Domain (Differential 2:1 MUX Function - D1 Selected)
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NBSG86ABAEVB
More Information About Evaluation Board
Design Considerations for >10 GHz operation
The following considerations played a key role to ensure
this evaluation board achieves high-end microwave
performance:
While the NBSG86A is specified to operate at 12 GHz,
this evaluation board is designed to support operating
frequencies up to 20 GHz.
• Optimal SMA connector launch
• Minimal insertion loss and signal dispersion
• Accurate Transmission line matching (50 W)
• Distributed effects while bypassing and noise filtering
SURFACE MOUNT CLIP
V
CC
OLS
Open Circuit Stub
T3
Surface Mount Clip
(l/4 @ 10 GHz)
C1
0
VTD1
0
D1
1
1
Rosenberger SMA
Rosenberger SMA
T1
T1
D1
VTD1
0
Q0
1
Rosenberger SMA
Rosenberger SMA
T1
T1
NBSG86A
VTD0
0
1
Q0
D0
1
1
Rosenberger SMA
Rosenberger SMA
T1
T1
D0
VTD0
0
C1
0
0
T3
(l/4 @ 10 GHz)
Open Circuit Stub
V
EE
Surface Mount Clip
Figure 8. Evaluation Board Schematic
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NBSG86ABAEVB
Table 3. Table 3. Parts List
Part No
Description
Manufacturer
ON Semiconductor
Rosenberger
WEB address
NBSG86ABA
SiGe Differential Smart Gate with Output Level Select
Gold plated connector
http://www.onsemi.com
http://www.rosenberger.de
32K243-40ME3
CO6BLBB2X5UX 2 MHz – 30 GHz capacitor
Dielectric Laboratories http://www.dilabs.com
Table 4. Board Material
Material
Thickness
Rogers 6002
Copper Plating
5.0 mil
32 mil
PIN 1
12.5 mil
1.37 mil
Dielectric (5.0 mil)
Thick Copper Base
Figure 9. Board Stack-up
Figure 10. Layout Mask for NBSG86A
5 dB
11 GHz
1 dB/
0 dB
START 1 GHz
1 GHz/
STOP 12 GHz
NOTE: The insertion loss curve can be used to calibrate out board loss if testing
under small signal conditions.
Figure 11. Insertion Loss
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NBSG86ABAEVB
EXAMPLE TIME DOMAIN MEASUREMENT RESULTS
900
800
700
600
500
400
300
200
100
9
8
7
6
5
4
3
2
1
OLS = V
CC
OLS = V - 0.8 V
CC
OLS = FLOAT
*OLS = V
EE
OLS = V - 0.4 V
CC
RMS JITTER
0
0
0
1
2
3
4
5
6
7
8
9
10
FREQUENCY (GHz)
Figure 12. VOUT/Jitter vs. Frequency (2:1 MUX Function)
(VCC - VEE = 3.3 V @ 255 C; Repetitive 1010 Input Data Pattern)
60
55
3.3 V
50
45
40
35
30
25
2.5 V
20
-40
-20
0
20
40
60
80
TEMPERATURE (°C)
Figure 13. tr. vs. Temperature and Power Supply
60
55
50
45
40
35
30
25
2.5 V
3.3 V
20
-40
-20
0
20
40
60
80
TEMPERATURE (°C)
Figure 14. tr. vs. Temperature and Power Supply
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NBSG86ABAEVB
EXAMPLE FREQUENCY DOMAIN MEASUREMENT RESULTS
50 dB
50 dB
0 dB
0 dB
10 dB
10 dB
-50 dB
-50 dB
START 1 GHz
1 GHz/
STOP 12 GHz
START 1 GHz
1 GHz/
STOP 12 GHz
Figure 15. NBSG86A: Small Signal Gain (S21)
D0/D0 - Q0/Q0
Figure 16. NBSG86A: Small Signal Gain (S21)
D1/D1 - Q0/Q0
50 dB
50 dB
10 dB
0 dB
10 dB
0 dB
-50 dB
-50 dB
START 1 GHz
1 GHz/
STOP 12 GHz
START 10 MHz
1 GHz/
STOP 12 GHz
Figure 17. NBSG86A: Large Signal Gain (S21)
D0/D0 - Q0/Q0
Figure 18. NBSG86A: Large Signal Gain (S21)
D1/D1 - Q0/Q0
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NBSG86ABAEVB
ADDITIONAL INFORMATION
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AND8075/D, Application Note, Board Mounting
Considerations for the FCBGA Packages
In all cases, the most up-to-date information can be found
on our website.
BRD8017/D, Brochure, Clock and Data Management
Solutions
• Sample orders for devices and boards
• New Product updates
• Literature download/order
• IBIS and Spice models
NBSG86A/D, Data Sheet, 2.5V/3.3V SiGe Differential
Smart Gate with Output Level Select
References
AND8077/D, Application Note, GigaCommE (SiGe)
SPICE Modeling Kit
ORDERING INFORMATION
Orderable Part No
Description
Package
Shipping
NBSG86ABA
SiGe Differential Smart Gate with Output Level Select
4X4 mm
FCBGA/16
100 Units/Tray
NBSG86ABAR2
SiGe Differential Smart Gate with Output Level Select
NBSG86A Evaluation Board
4X4 mm
FCBGA/16
500 Units/Reel
NBSG86ABAEVB
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NBSG86ABAEVB
Notes
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NBSG86ABAEVB
Notes
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NBSG86ABAEVB
GigaComm is a trademark of Semiconductor Components Industries, LLC.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make
changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any
particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all
liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or
specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be
validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others.
SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
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