Datasheet Texas Instruments CDCVF111FNG4
Manufacturer | Texas Instruments |
Series | CDCVF111 |
Part Number | CDCVF111FNG4 |
1:9 Differential LVPECL Clock Driver 28-PLCC -40 to 85
Datasheets
1:9 Differential LVPECL Clock Driver datasheet
PDF, 951 Kb, Revision: B, File published: Jun 7, 2002
Extract from the document
Prices
Status
Lifecycle Status | Active (Recommended for new designs) |
Manufacture's Sample Availability | Yes |
Packaging
Pin | 28 |
Package Type | FN |
Industry STD Term | PLCC |
JEDEC Code | S-PQCC-J |
Package QTY | 37 |
Carrier | TUBE |
Device Marking | CDCVF111 |
Width (mm) | 11.51 |
Length (mm) | 11.51 |
Thickness (mm) | 4.06 |
Pitch (mm) | 1.27 |
Max Height (mm) | 4.57 |
Mechanical Data | Download |
Parametrics
Input Frequency(Max) | 650 MHz |
Input Level | LVPECL |
Number of Outputs | 9 |
Operating Temperature Range | -40 to 85 C |
Output Frequency(Max) | 650 MHz |
Output Level | LVPECL |
Package Group | PLCC |
Package Size: mm2:W x L | 28PLCC: 132 mm2: 11.51 x 11.51(PLCC) PKG |
Rating | Catalog |
VCC | 3.3 V |
VCC Out | 3.3 V |
Eco Plan
RoHS | Compliant |
Application Notes
- Using TI's CDC111 W/SLK2501 Serial Gigabit Transceiver for SONET, EthernetPDF, 72 Kb, File published: Oct 31, 2001
SONET/SDH and gigabit ethernet applications all have stringent timing requirements, which mandate the use of low-skew, low-jitter clock distribution. Texas Instruments has developed two products targeting these systems applications. The first product is the CDCVF111, a 1:9 low-skew, low-jitter differential LVPECL clock driver. The second is the SLK2501, a multirate (OC-48/24/12/3) serial gigabit t - Using TI's CDC111/CDCVF111 W/ TLK3104SA Serial Transceiver for Gigabit EthernetPDF, 79 Kb, File published: Oct 31, 2001
This application report discusses jitter transfer of TI's CDC111/CDCVF111 clock drivers when driving TI's TLK3104 serial gigabit transceiver. This report summarizes worst case peak-to-peak and RMS jitter measurements taken at various points, as indicated in Figures 1 and 2. Two different clock sources are used to provide the reference clock signal for the clock drivers, and the output of each cloc - Jitter Performance of TI's CDC111/CDCVF111PDF, 149 Kb, File published: Oct 29, 2001
This application report discusses various jitter measurements of TI?s CDC111/CDCVF111 while being driven by three different clock sources (VCXOs). The data contained in this report shows that the CDC111/CDCVF111 does not add more than 3 ps of peak-to-peak jitter. Hence, the CDC111 and CDCVF111 are ideal for various SONET and Gigabit Ethernet applications where skew and jitter are of major concern. - Output Jitter of CDC111/CDCVF111 in ASIC Networking ApplicationPDF, 361 Kb, File published: Nov 2, 2001
This report contains a number of peak-to-peak and cycle-to-cycle jitter measurements of TI?s CDC111 and CDCVF111 clock driver. In this ASIC event, both the CDC111/CDCVF111 clock drivers are used as a master clock distribution for the Gandalf Macro Family Testchip. Comprehensive jitter data as well as output signal levels were taken and thus are included for completeness. - DC-Coupling Between Differential LVPECL, LVDS, HSTL, and CMLPDF, 135 Kb, File published: Feb 19, 2003
- AC Coupling Between Differential LVPECL, LVDS, HSTL and CML (Rev. C)PDF, 417 Kb, Revision: C, File published: Oct 17, 2007
This report provides a quick reference of ac-coupling techniques for interfacing between different logic levels. The four differential signaling levels found in this reportare low-voltage positive-referenced emitter coupled logic (LVPECL), low-voltage differential signals (LVDS), high-speed transceiver logic (HSTL), and current-modelogic (CML). From these four differential signaling levels, 16
Model Line
Series: CDCVF111 (4)
- CDCVF111FN CDCVF111FNG4 CDCVF111FNR CDCVF111FNRG4
Manufacturer's Classification
- Semiconductors > Clock and Timing > Clock Buffers > Differential