Abstract
Multiple resolutions have become a new feature required in ultra-fast data acquisition systems (UF-DASs) for various high-end applications, especially for large-scale physical experiments and radar equipment. However, plenty of repetitive efforts are paid to build various UF-DASs with different resolutions for many similar purposes. In this paper, a system-level sampling solution featuring multi-resolution is explored for UF-DASs to make the trade-off between accuracy and speed. Firstly, a resolution enhancement mechanism based on a time-synchronized sampling technique is studied more generally with probabilistic and statistical theory, and its applicable premise is discussed quantificationally at the same time. Then, a hardware-based reconfigurable structure for the purpose of multi-resolution high-speed sampling is discussed with the combination of time-interleaved and time-synchronized sampling methods. Furthermore, to verify the proposed theory, a prototype with a maximal 20GSPS sampling rate and different resolutions of 8,9,10-bit is established. The experimental results show that three vertical resolutions of 8, 9 and 10-bit are achieved in the same prototype, and the effective-number-of-bit (ENOB) in the two higher resolution modes has been improved remarkably from a single low-resolution analog-to-digital converter (ADC). Therefore, the proposed theory and multi-resolution sampling solution are important guides to the resolution trade-off requirement in ultra-fast acquisition systems.
Highlights
Ultra-fast data acquisition (UF-DAQ) technique plays an important role in modern electronic system design and testing for various high-end applications
We focus on resolution enhancement solutions for UF-DAQ systems at high sampling rates
Compared with the 8-bit and 9-bit sampling mode, it can be seen that the waveform in 10-bit mode is the cleanest and closest to the real signal. These results indicate that high resolution implemented by TSADC has an intuitive effect from the time domain observation
Summary
Ultra-fast data acquisition (UF-DAQ) technique plays an important role in modern electronic system design and testing for various high-end applications. After summing their sampled data into a more-bit stream (switch on position ‘2’ in FIGURE 1), high quantization resolution of M times of single ADC can be achieved This is another hardware parallel sampling mode, called TSADC. QUANTIZATION MODEL Since the introduced noise in DAS is derived from active devices (such as amplifiers and ADC internal circuitry), these types of noise usually behave as thermal noises and a certain amount of them are generated undesirably It occurs in all real sampled-data systems even with a direct-current (DC) input signal, which is the reason for the existence of code transition noise in the transfer function of any converters [22]. This special type of sampling is called an ‘area sampling’ in literature [24] and the ‘sampling period’ is q
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