Description
DAC8718SPAG Texas Instruments - Yeehing Electronics
Octal Low-Power 16-Bit +/-16.5V Output Serial Input Digital-to-Analog Converter
Pricing (USD)
Quantity | Unit Price |
1 — 99 | 39.765 |
100 — 249 | 35.346 |
250 — 999 | 29.057 |
1,000 + | 20.79 |
The above prices are for reference only.
Specifications
Manufacturer | Texas Instruments |
Product Category | Digital to Analog Converters - DAC |
RoHS | Y |
Series | DAC8718 |
Resolution | 16 bit |
Number of Channels | 8 Channel |
Interface Type | Serial, 3-Wire, SPI |
Supply Voltage - Max | 20 V |
Supply Voltage - Min | 5 V |
Minimum Operating Temperature | - 40 C |
Maximum Operating Temperature | + 105 C |
Mounting Style | SMD/SMT |
Package / Case | TQFP-64 |
Packaging | Tray |
Features | SDO |
Height | 1 mm |
Number of Converters | 8 Converter |
Power Consumption | 115 mW |
Architecture | Resistor-String |
Brand | Texas Instruments |
Development Kit | DAC8718EVM |
Gain Error | 0.01 % FSR |
Moisture Sensitive | Yes |
Operating Supply Voltage | 9 V, 12 V, 15 V, 18 V |
Product Type | DACs - Digital to Analog Converters |
Factory Pack Quantity | 160 |
Subcategory | Data Converter ICs |
Unit Weight | 0.012720 oz |
For more information, please refer to datasheet
Documents
DAC8718SPAG Datasheet |
More Information
The DAC8718 is a low-power, octal, 16-bit digital-to-analog converter (DAC). With a 5V reference, the output can either be a bipolar ±15V voltage when operating from dual ±15.5V (or higher) power supplies, or a unipolar 0V to +30V voltage when operating from a +30.5V (or higher) power supply. With a 5.5V reference, the output can either be a bipolar ±16.5V voltage when operating from dual ±17V (or higher) power supplies, or a unipolar 0V to +33V voltage when operating from a +33.5V (or higher) power supply. This DAC provides low-power operation, good linearity, and low glitch over the specified temperature range of –40°C to +105°C. This device is trimmed in manufacturing and has very low zero-code and gain error. In addition, system level calibration can be performed to achieve ±1 LSB bipolar zero/full-scale error with bipolar supplies, or ±1 LSB zero code/full-scale error with a unipolar supply, over the entire signal chain. The output range can be offset by using the DAC offset register.