
Manufacturer Part #
NB6L295MNG
NB Series 3.3 V 3 GHz Dual Channel Programmable Clock/Data Delay - QFN-24
Product Specification Section
onsemi NB6L295MNG - Product Specification
Shipping Information:
Item cannot ship to certain countries. See List
Item cannot ship to following countries:
ECCN:
EAR99
PCN Information:
N/A
File
Date
Part Status:
Active
Active
onsemi NB6L295MNG - Technical Attributes
Attributes Table
Type: | Differential |
Clock Input Frequency - Max: | 1.5GHz |
Supply Voltage-Nom: | 2.4V to 3.6V |
Package Style: | QFN-24 |
Mounting Method: | Surface Mount |
Features & Applications
The NB6L295MNG is a dual channel programmable clock/data delay with differential LVPECL outputs, available in a QFN-24 package.
The NB6L295 is versatile in that two individual variable delay channels, PD0 and PD1, can be configured in one of two operating modes, a Dual Delay or an Extended Delay.
Features:
- Input Clock Frequency > 1.5 GHz with 550 mV VOUTPP
- Input Data Rate > 2.5 Gb/s
- Programmable Delay Range: 0 ns to 6 ns per Delay Channel
- Programmable Delay Range: 0 ns to 11.2 ns for Extended Delay Mode
- Total Delay Range: 3.2 ns to 8.8 ns per Delay Channel
- Total Delay Range: 6 ns to 17 ns in Extended Delay Mode
- Monotonic Delay: 11 ps Increments in 511 Steps
- Linearity 20 ps, Maximum
- 100 ps Typical Rise and Fall Times
- 3 ps Typical Clock Jitter, RMS
- 20 ps Pk−Pk Typical Data Dependent Jitter
- LVPECL, CML or LVDS Differential Input Compatible
- LVPECL, LVCMOS, LVTTL Single−Ended Input Compatible
- 3−Wire Serial Interface
- Input Enable/Disable
- Operating Range: VCC = 2.375 V to 3.6 V
- LVPECL Output Level; 780 mV Peak−to−Peak, Typical
- Internal 50 Ω Input Termination Provided
- −40°C to 85°C Ambient Operating Temperature
- 24−Pin QFN, 4 mm x 4 mm
- These are Pb−Free Devices*
Pricing Section
Global Stock:
0
USA:
0
On Order:
0
Factory Lead Time:
18 Weeks
Quantity
Unit Price
92
$16.36
184+
$16.21
Product Variant Information section
Available Packaging
Package Qty:
92 per Tube
Package Style:
QFN-24
Mounting Method:
Surface Mount