MC100LVEL13DW vs MC100LVEP11DT
| Part Number |
|
|
| Category | Clock/Timing - Clock Buffers, Drivers | Clock/Timing - Clock Buffers, Drivers |
| Manufacturer | ON Semiconductor | ON Semiconductor |
| Description | IC CLOCK BUFFER 1:3 1GHZ 20-SOIC | IC CLOCK BUFFER 1:2 3GHZ 8-TSSOP |
| Package | Tube | Tube |
| Series | - | - |
| Type | Fanout Buffer (Distribution) | Fanout Buffer (Distribution) |
| Voltage - Supply | - | - |
| Operating Temperature | - | - |
| Mounting Type | Surface Mount | Surface Mount |
| Package / Case | 20-SOIC (0.295\", 7.50mm Width) | 8-TSSOP, 8-MSOP (0.118\", 3.00mm Width) |
| Supplier Device Package | 20-SOIC | 8-TSSOP |
| Output | - | - |
| Frequency - Max | - | - |
| Number of Circuits | - | - |
| Input | - | - |
| Ratio - Input:Output | 1:3 | 1:2 |
| Differential - Input:Output | - | - |
-
1. What are the main applications of clock buffers?
Clock buffers are widely used in systems that require the distribution of clock signals to multiple devices, such as computer motherboards, servers, communication equipment, data centers, and industrial control systems, to ensure synchronized operation of all devices.
-
2. How can clock buffers reduce jitter?
High quality clock buffers are typically designed with low jitter characteristics to ensure phase consistency of output signals and reduce phase noise during transmission. This is crucial for high-precision clock allocation, such as in communication and data transmission applications.
-
3. Does the clock driver support differential signals?
Yes, many clock drivers support differential signaling, such as LVDS, CML, and HCSL, which can provide higher anti-interference capabilities, especially in high-speed signal transmission applications.
-
4. How to evaluate the performance of clock drivers?
When evaluating clock drivers, several key parameters need to be considered:
Driving capability (load capacity)
Output signal integrity
Phase noise and jitter
Power noise suppression
Power supply voltage range and power consumption
