Description
ADS5517IRGZR Texas Instruments - Yeehing Electronics
11-Bit, 200-MSPS Analog-to-Digital Converter (ADC)
Pricing (USD)
Quantity | Unit Price |
1 — 99 | 48.741 |
100 — 249 | 43.326 |
250 — 999 | 35.616 |
1,000 + | 25.49 |
The above prices are for reference only.
Specifications
Manufacturer | Texas Instruments |
Product Category | Analog to Digital Converters - ADC |
RoHS | Y |
Series | ADS5517 |
Mounting Style | SMD/SMT |
Package / Case | VQFN-48 |
Resolution | 11 bit |
Number of Channels | 1 Channel |
Sampling Rate | 200 MS/s |
Input Type | Differential |
Interface Type | Parallel |
Architecture | Pipeline |
Reference Type | External, Internal |
Analog Supply Voltage | 3.3 V |
Digital Supply Voltage | 3 V to 3.6 V |
SNR - Signal to Noise Ratio | 67.1 dB |
Minimum Operating Temperature | - 40 C |
Maximum Operating Temperature | + 85 C |
Packaging | Reel |
Features | Low Power |
Height | 0.9 mm |
Length | 7 mm |
Number of Converters | 1 Converter |
Output Type | LVDS |
Power Consumption | 1.23 W |
Width | 7 mm |
Brand | Texas Instruments |
Development Kit | ADS5517EVM |
DNL - Differential Nonlinearity | +/- 1 LSB |
ENOB - Effective Number of Bits | 10.8 Bit |
INL - Integral Nonlinearity | +/- 1.5 LSB |
Moisture Sensitive | Yes |
Operating Supply Voltage | 3 V to 3.6 V |
Pd - Power Dissipation | 1.4 W |
Product Type | ADCs - Analog to Digital Converters |
SFDR - Spurious Free Dynamic Range | 84 dB |
SINAD - Signal to Noise and Distortion Ratio | 66 dB |
Factory Pack Quantity | 2500 |
Subcategory | Data Converter ICs |
Unit Weight | 0.004868 oz |
For more information, please refer to datasheet
Documents
ADS5517IRGZR Datasheet |
More Information
ADS5517 is a high performance 11-bit, 200-MSPS A/D converter. It offers state-of-the art functionality and performance using advanced techniques to minimize board space. With high analog bandwidth and low jitter input clock buffer, the ADC supports both high SNR and high SFDR at high input frequencies. It features programmable gain options that can be used to improve SFDR performance at lower full-scale analog input ranges.