The goal of this research is to develop differential amplifiers based on amorphous indium-gallium-zinc-oxide (a-IGZO) thin-film transistors (TFTs). First, the bottom-gate a-IGZO TFTs were optimized in terms of the sequence of processing steps, and the thickness and annealing time of the a-IGZO channel. Next, common-source amplifiers with either resistive loads or active loads were implemented using the optimized a-IGZO TFTs. Afterwards, two common-source amplifiers with identical loads were interconnected through via-holes to form the differential amplifier, which was driven by either an ideal current source or a transistor current source. Last, both common-source amplifiers and differential amplifiers were connected to PVDF piezoelectric tactile sensors, and their abilities to reject common-mode signals were analyzed. 　　The a-IGZO TFT has an inverted-staggered bottom-gated structure. Because the deposition process of SiOx passivation layer can introduce defects in the a-IGZO channel and the HfO2 gate dielectric, causing an increase of the threshold voltage and subthreshold swing, the passivation layer was deposited followed by an annealing process of the a-IGZO channel. The optimal channel thickness and annealing time are 22.5 nm and 60 mins, respectively. The optimal a-IGZO TFT has an saturation mobility 3.94 cm2V-1s-1, threshold voltage 4.31 V, subthreshold swing 0.22 V/dec, and on/off current ratio of 8.5×108, respectively. 　　The optimized a-IGZO TFTs were then integrated to form common-source amplifiers with either a resistive load of 1 M or an active load using a geometric aspect ratio, (W/L)active / (W/L)load, of 16. At a supplied voltage (VDD) of 10 V, the voltage gains are 6 V/V and 3 V/V, respectively, the cutoff frequencies are 542.2 Hz and 2.13 kHz, respectively. Both voltage gains were close to the theoretical values. Because the equivalent capacitance of the entire amplifier circuit with an active load is lowered due to the series connection of two TFTs, its cutoff frequency is higher than that of the amplifier with a resistive load. Next, differential amplifiers were formed by integrating two common-source amplifiers with identical loads. The amplifiers were either driven by an ideal current source or a transistor current source. For differential amplifiers driven by an ideal current source, both the low-frequency gain and the cutoff frequency are close to that of the individual common-source amplifier. For differential amplifiers driven by a transistor current source, the cut-off frequency is increased, because the driving transistor connected in series can reduce the equivalent capacitance of the entire circuit. 　　Finally, the common-source amplifier and differential amplifier with an active load and driven by an ideal current source were connected to PVDF piezoelectric tactile sensors. The result shows that the common-source amplifier cannot reject the common-mode signal and amplifies the noise and signal simultaneously, giving a signal-to-noise ratio (SNR) of 186.2 (22.7 dB), while the differential amplifier can effectively reduce the common-mode signal, yielding a SNR of 549.5 (27.4 dB).