Permasalahan energi di wilayah perkotaan semakin kompleks seiring dengan meningkatnya kebutuhan listrik dan keterbatasan ruang untuk instalasi pembangkit listrik tenaga surya konvensional. Panel Surya transparan menawarkan solusi inovatif yang kedepannya bisa terus berkembang seiring perkembangan PLTS (Pembangkit Listrik Tenaga surya). Penelitian ini juga bertujuan untuk memperbandingkan kinerja panel surya transpran dari keempat sisi, yaitu Timur, Barat, Selatan, dan Utara . Mengevaluasi besarnya kerugian-kerugian pada panel surya transparan berdasarkan orientasi-orientasi yang berpengaruh pada kerugian, yaitu Shading Loss, IAM Loss, Temperature Loss, Mismatch Loss, dan Ohmic Wiring Loss. Dan mengkaji distribusi produksi energi pada panel surya tranpasarn pada musim kemarau dan musim hujan. Penelitian menggunakan Pvsyst untuk menganalisi potensi energi panel surya transparan pada bagunan bertingkat. Simulasi dilakukan untuk empat sisi bangunan (Timur, Barat, Selatan, Utara) selamat satu tahun. Hasil simulasi menunjukkan sisi Timur menghasilkan energi tertinggi (7.982,5 kWh/tahun), diikuti Barat (7.931,2 kWh/tahun), Utara (6.799,9 kWh/tahun), dan Selatan (5.360,3 kWh/tahun). Produksi energi meningkat pada musim kemarau (Mei-Oktober), terutama di sisi Utara dan Timur, sementara menurun pada musim hujan (November-April), terutama di sisi Selatan. Kerugian energi terbesar disebabkan oleh IAM Loss (Timur dan Barat), Temperature Loss (Utara), dan Shading Loss (Selatan). Hasil penelitian, panel surya transparan berpotensi besar sebagai pengganti kaca pada bangunan bertingkat, terutama di wilayah perkotaan. Sisi Timur dan Barat menunjukkan kinerja terbaik, sementara sisi Selatan memiliki produksi energi terendah. Faktor musim dan orientasi pemasangan sangat memengaruhi produksi energi.

Energy problems in urban areas are increasingly complex along with the increasing demand for electricity and limited space for conventional solar power plant installations. Transparent solar panels offer innovative solutions that can continue to grow in the future along with the development of solar power plants (solar power plants). This study also aims to compare the performance of transprannal solar panels from four sides, namely East, West, South, and North. Evaluate the magnitude of losses in transparent solar panels based on the orientations that affect the losses, namely Shading Loss, IAM Loss, Temperature Loss, Mismatch Loss, and Ohmic Wiring Loss. And examine the distribution of energy production in tranpasarn solar panels in the dry and rainy seasons. The research uses Pvsyst to analyze the energy potential of transparent solar panels in multi-storey buildings. Simulations were carried out for four sides of the building (East, West, South, North) surviving one year. The simulation results show that the East side produces the highest energy (7,982.5 kWh/year), followed by the West (7,931.2 kWh/year), the North (6,799.9 kWh/year), and the South (5,360.3 kWh/year). Energy production increases in the dry season (May-October), especially on the North and East sides, while it decreases in the rainy season (November-April), especially on the South side. The largest energy losses are caused by IAM Loss (East and West), Temperature Loss (North), and Shading Loss (South). As a result of the research, transparent solar panels have great potential as a substitute for glass in high-rise buildings, especially in urban areas. The East and West sides showed the best performance, while the South side had the lowest energy production. Seasonal factors and installation orientation greatly affect energy production.