Abstract
This paper presents a compact and simple design of adjustable triangular and square wave functional generators employing fundamental cells fabricated on a single integrated circuit (IC) package. Two solutions have electronically tunable repeating frequency. The linear adjustability of repeating frequency was verified in the range between 17 and 264 kHz. The main benefits of the proposed generator are the follows: A simple adjustment of the repeating frequency by DC bias current, Schmitt trigger (threshold voltages) setting by DC driving voltage, and output levels in hundreds of mV when the complementary metal-oxide semiconductor (CMOS) process with limited supply voltage levels is used. These generators are suitable to provide a simple conversion of illuminance to frequency of oscillation that can be employed for illuminance measurement and sensing in the agriculture applications. Experimental measurements proved that the proposed concept is usable for sensing of illuminance in the range from 1 up to 500 lx. The change of illuminance within this range causes driving of bias current between 21 and 52 μA that adjusts repeating frequency between 70 and 154 kHz with an error up to 10% between the expected and real cases.
Highlights
The triangular and square wave waveform generators are key subparts of many analog and mixed circuits [1]
Such phenomenon is caused by the implementation of nonadjustable active elements in key parts of a generator
The bias current (IB ) adjusted from 5 up to 140 μA has been used for tunability of repeating frequency (f 0 ) of the generators
Summary
The triangular and square wave waveform generators are key subparts of many analog and mixed circuits (clock generation, pulse width modulation, DC-DC converters, etc.) [1]. Using them leads to very limited electronic adjustability of the repeating frequency in the generators (e.g., see comparison in [4]) Such phenomenon is caused by the implementation of nonadjustable active elements in key parts of a generator (e.g., see once again comparison in [4], where the AD844 device is used in an integrator or comparator). Result 0.5 mW available for simulations only (not for experiment), 2 result 1.45 mW available for simulations only (not for experiment); * these solutions are only partially electronically controlled (duty cycle tested); S: Simulated; M: Measured; N/A: Not available; Note: Information about the area of active elements in cited works is not available. (c)transconductance operational conveyor generation (b) voltage and (c) operational transconductance amplifier (OTA). amplifier (OTA)
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