A low power sensor read-out circuit has been implemented in
0.35 µm CMOS technology that
consumes only 400 µW of power
and occupies an area of 0.66 mm2. The circuit is capable of converting the current signal from any generic biosensor into an
amplitude shift keying (ASK) signal. The on-chip potentiostat biases the chemical sensor
electrodes to create the sensor current which is then integrated and buffered to generate a
square wave with a frequency proportional to the sensor current level. A programmable
frequency divider is incorporated to fix the ASK envelope frequency to be inbetween
20 Hz and 20 kHz, which is within the audible range of human hearing. The entire
transmitter block operates with a supply voltage as low as 1.5 V, and it can be
easily powered up by an external RF source. Test results emulate the simulation
results with good agreement and corroborate the efficacy of the designed system.
A wireless power transfer system using an inductive link has been demonstrated for implantable sensor applications. The system is composed of two primary blocks: an inductive power transfer unit and a backward data communication unit. The inductive link performs two functions: coupling the required power from a wireless power supply system enabling battery-less, long-term implant operation and providing a backward data transmission path. The backward data communication unit transmits the data to an outside reader using FSK modulation scheme via the inductive link. To demonstrate the operation of the inductive link, a board-level design has been implemented with high link efficiency. Test results from a fabricated sensor system, composed of a hybrid implementation of custom-integrated circuits and board-level discrete components, are presented demonstrating power transmission of 125 mW with a 12.5% power link transmission efficiency. Simultaneous backward data communication involving a digital pulse rate of up to 10 kbps was also observed.
A low-power low-voltage analog signal processing circuit has been designed, fabricated, and tested. The circuit is capable of processing an analog sensor current and producing an ASK modulated digital signal with modulating signal frequency proportional to the sensor current level. An on-chip regulator has been included to stabilize the supply voltage received from an external RF power source. The circuit can operate with a power supply as low as 1 V and consumes only about 20 µW of power, which is therefore very suitable for implantable biomedical applications. The whole chip was laid out and fabricated in a 0.35 µm bulk CMOS technology. Experimental results show good agreement with the simulation results.
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