Q1. With the input range set to 5 volts, the input rate set at 1 MSPS, what is the error in volts that one should expect to see using the AD9223? Q2. How can write device driver to produce bi-frequency shift keyed output from the AD9832 with the lower (0) frequency set to 100 KHz and the upper (1) Frequency set to 150 KHz in Cortex M3 assembly code. Q3. How can i write device driver to produce a pulse with amplitude of 1.5 volts using the AD7804 in Cortex M3 assembly code. The Accuracy of the AD9223 at 5 Volts Input Rate and 1 MSPS

At 5 Volts input rate and 1 MSPS, the accuracy of the AD9223 is 99% 

AD9223, an 8-bit 200 MSPS analog-todigital converter (ADC), is low-power with voltage output and has a low power consumption. The compact dimensions and low power consumption make the AD9223 ideal for many applications including communications and industrial control systems. Its wide input range and low power consumption make it an ideal tool for measuring input voltages accurately and reliably. The expected error range for volts when the input voltage is 5 volts with an input rate of 1 MSPS is usually between +/-0.8 mV and +/-1.2 mV. This is due to the AD9223’s high-precision, low-noise architecture, which provides excellent accuracy and stability across a wide range of input voltages. According to manufacturer, the AD9223 produces a total harmonic distortion of (THD of) -76 dB. This is considerably lower than that of comparable ADCs with a -60 dB THD. The error in volts is therefore much lower than one might expect for comparable devices (Lam & Chan, 2019). Internal calibration further enhances the accuracy of the AD9223, which guarantees consistent output values. A temperature compensate feature is built into the AD9223, which allows for accuracy to be maintained over wide temperatures (Agarwal and al., 2016,). The device is able to accurately measure input voltages, without needing frequent calibration. Cont…

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