With the advance of the CMOS process technology, more and more circuits are suffering from the short channel effect, which becomes a main issue as the technology marches to deep-submicron fields. Compared with the former process technology, the influence of the short channel effect on the design of operational transconductor amplifier (OTA) becomes more serious and makes the circuit performance deviated from the ideal voltage-current equation, especially the performance of the linearity. Therefore, various researches to compensate short channel effects have been published. In the deep-submicron technology, numerous new challenges appear because of the lower supply voltage and lower threshold voltage. Simultaneously, the power consumption which is directly proportional to the supply voltage can be reduced and it is expectant for the portable devices. Therefore, designs and researches for new CMOS deep-submicron technology are highly expected. In this thesis, a new concept of the HD3 feedforward technique, which can compensate the influences of the short channel effect, is proposed for linearity improving. Meanwhile, the method is applied to two traditional transconductor structures, including pseudo differential and source degeneration. Moreover, a transconductance-C filter based on proposed OTA was also designed. The pseudo-differential transconductor with HD3 feedforward technique works under a 1.2V supply voltage with 0.47mW power consumption. The measurement results show the HD3 of -62dB with 0.4-Vpp 50MHz input signal. The chip is fabricated in TSMC 0.18μm CMOS technology occupies 0.35×0.35mm2. The source-degeneration transconductor with HD3 feedforward technique shows the measurement result of -56dB in HD3 with 0.6-Vpp 10MHz input signal under a 1.5V supply voltage with 1.25mW power consumption. The chip also fabricated in TSMC 0.18μm CMOS technology occupies 0.67×0.95mm2.