在本論文中,提出在玻璃基板中介層整合二維陣列高分子聚合物波導設計4 x 4通道 x 25-Gbps光連接發射模組,以玻璃基板為中介層,將4 x 4面射型雷射,以覆晶封裝在玻璃基板上完成,並將被動電路,透鏡整合至玻璃基板上,並整合高分子聚合物的波導,完成此模組的設計。 發射端光學模擬在各個不同的通道上的耦合效率,耦合效率在45%到49%之間,並進行光學串音的分析,在-30dB以下皆可忽略。 高頻傳輸線的設計,目前只有設計單端傳輸線設計,包含兩部分設計,第一部分設計為玻璃基板上面傳輸線的設計,在62.5-GHz,其反射損耗為-17dB,插入損耗為-0.2dB。第二部分設計為經過從玻璃基板上方的接合墊,經過銅柱,到玻璃基板底側的傳輸線,最佳的設計為在直徑40 μm,在62.5-GHz其反射損耗為-17dB,其插入損耗為-0.25dB。 ;In this thesis, 4 x 4-Channel x 25-Gbps Optical Interconnect Transmitter Based on Glass Interposer Combined with Two-Dimensional Polymer Waveguides is proposed. 4 x 4 VCSEL was flip-chip mounted to the glass. The microlens and polymer waveguide will be integrated on glass interposer. The coupling efficiency on each of the different channels of the transmitter are between 45% and 49%.The analysis of optical crosstalk are below -30dB, so they can be ignored. The high-frequency transmission line is currently single-ended transmission line design, including two parts design. The first part is designed for the transmi- ssion line on the top side of the glass substrate. At 62.5-GHz, the return loss is -17dB and the insertion loss is -0.2dB. The second part is designed to pass fr- om the bonding pad on the glass substrate, through the copper column, to the bottom of the glass substrate transmission line. The best design for the diameter of copper column is 40 μm. In this situation, the return loss is -17dB, the insertion loss of -0.25dB.