New 2 2 Sigma Delta Modulators for Different Applications

This work presents the design of a new 2-2 programmable sigma delta modulator architecture, for different applications, this transformation design of the ΣΔ modulator low-pass, band-pass and high-pass or vice versa with loopbacks addition, which improved the linearity of the converter and reduced the quantization noise. In this work, the MASH structure enables the implementation of stable and high-order modulator. This makes low voltage and low power applications ideal. The simulation result for sigma delta modulator for biomedical applications exhibit a signal to noise ratio is 95 dB @ 250Hz bandwidth and a 75dB @ 200KHz ,85dB @1MHz for pass band modulator. The SNR is about 70dB for 5MHz bandwidth and for high pass application. This tool will allow a development contribution and characterize a system optimization set from the start while remaining at a high level of design that is suitable for electronic systems and models VHDL-AMS, RF, Biomedical.

A high-precision interface for tunneling magnetoresistance sensors with 0.15 nT/√Hz resolution

The tunneling magnetoresistance (TMR) with high-resolution digital output is widely used in military and civil fields. In this work we proposed a low-noise read-out circuit and a four-order fully differential sigma-delta modulator for TMR sensors. In the read-out circuit, we used symmetrical cascade for good matching. We used correlated double sampling (CDS) technique to improve the conversion accuracy of the modulator. In switched capacitor circuits we used time-division multiplexing to suppress charge injection and clock feedthrough. The high-precision application specific integrated circuit (ASIC) chip was fabricated by a 0.35 [Formula: see text]m CMOS process from Shanghai Huahong foundry. The TMR sensor was placed in an environment of three-layer magnetic shielding for test. The active area of the ASIC is only about [Formula: see text]. At a sampling frequency of 20 kHz, the TMR magnetometer consumes 77 mW from a single 5 V supply; the sigma-delta modulator for TMR can achieve an average noise floor of −141 dBV. The magnetometer works at a full scale (FS) of [Formula: see text], it can achieve a nonlinearity of 0.2% FS and a resolution of 0.15 nT/Hz[Formula: see text] over a signal bandwidth.

Power Electronics Programmable Voltage Source with Reduced Ripple Component of Output Signal Based on Continuous-Time Sigma-Delta Modulator

In this work, an idea of a wideband, precision, power electronics programmable voltage source (PVS) is presented. One of the basic elements of the converter, the control section, contains a continuous-time sigma-delta modulator (SDM) with a pair of interconnected complementary comparators, which represents a new approach. In this case, the SDM uses comparators with a dynamic hysteresis loop (DHC) that includes an AC circuit rather than an R-R network. Dynamic hysteresis is a very effective way of eliminating parasitic oscillation during the signal transition at the input of the comparator; it also affects the frequency characteristics and, especially, the phase properties of the comparator, and this phenomenon is exploited in the proposed converter. The main disadvantage of all pulse-modulated converters is the presence of a ripple component in the output voltage (current), which reduces the quality of the output signal and may cause high-frequency disturbances. A basic feature of PVS is a lower RMS value for the pulse modulation component in the output voltage of the converter, compared to the typical value. Another important feature of the proposed converter is the ability of precise mapping of the output voltage to the reference (input) signal. The structure of the control circuit is relatively simple—no complex, digital components are used. Due to the high frequency of the SDM output bit-stream, the simulation model of the power stage of PVS is based on the power modules with gallium-nitride field effect transistors (GaN FETs). The work discusses the rules of PVS operations and the results from PVS simulation model studies as well as highlights the possible application fields for systems with a PVS.

Processing Electrocardiographic Signals using a Custom Designed Sigma-Delta Modulator

This paper introduces the experimental results obtained after processing an electrocardiographic signal by a full-custom, low-complexity, Sigma-Delta Modulator integrated circuit, designed and fabricated using the C5N CMOS technology available through MOSIS. By exploiting a large oversampling ratio, it was possible to obtain an effective number of bits equal to 11 at the proposed single-bit modulator’s output. The resulting bitstream was captured with a logic-state analyzer and processed offline. After decimation and digital filtering, the electrocardiographic signal was reconstructed and plotted in the time domain. Commonly referred quality metrics over the retrieved signal were calculated. A total signal-to-noise and distortion ratio, superior to 66[Formula: see text]dB, was achieved by analyzing the entire system. The proposed approach shows the feasibility of processing electrocardiographic signals using low-cost and straightforward CMOS technology circuits. Since the proposed converter uses a single voltage supply of 1.5[Formula: see text]V, exhibits a power consumption of 38[Formula: see text][Formula: see text]W, and uses a silicon area of 0.052[Formula: see text]mm2, it is suitable for single battery-operated systems on a chip.