本研究提出並實現了一種集總元件式參數放大器（Lumped-Element Josephson, LJPA），並建立完整的自動化量測與資料分析流程以驗證其性能。結合 LabVIEW 與 Python 平台，系統可自動掃描磁通偏壓與幫浦功率，同步分析反射參數 $S_{21}$ 並擬合共振頻率對磁通的變化，以萃取零磁通電流 ($I_{\text{zero,flux}}$) 與磁通電流週期性（$I_{periodicity}$）等參數。量測結果顯示，本研究所製作之 LJPA 於幫浦頻率 11.2–11.9 GHz、磁通偏壓 0.33–0.45 $\Phi_0$ 範圍內表現最佳，增益可達 25 dB，頻寬約 100–200 MHz，具穩定且可重現之放大特性。進一步透過條件分析模組（$\text{Gain} > 18~\text{dB}$、$\text{BW} > 0.03~\text{GHz}$ ），能自動辨識可操作區域並執行細部掃描，以鎖定最佳操作點。本研究成功建立 LJPA 操作參數搜尋量測與分析流程，不僅提升操作效率與資料準確性，也驗證集總式設計在高增益與寬頻放大應用上的潛力。

This study presents the design and characterization of a lumped-element Josephson Parametric Amplifier (LJPA) and establishes a fully automated measurement and analysis framework. By integrating LabVIEW and Python, the system automatically scans flux bias and pump power, analyzes reflection data ($S_{21}$), and extracts key parameters such as the zero-flux current ($I_{\text{zero,flux}}$) and flux current periodicity.

Experimental results show that the LJPA exhibits optimal performance at pump frequencies of 11.2–11.9 GHz and flux bias between 0.33–0.45 $\Phi_0$, achieving up to 25 dB gain and 100–200 MHz bandwidth with stable and reproducible behavior. A conditional analysis module ($\text{Gain} > 18~\text{dB}$, $\text{Bandwidth} > 0.03~\text{GHz}$ ) further identifies the optimal operation region for precise tuning.

This study successfully established a complete measurement and analysis workflow for searching the operating parameters of LJPA, which not only improves operational efficiency and data accuracy but also verifies the potential of the lumped-element design for achieving high gain and wideband amplification applications.

[1] Z. R. Lin, K. Inomata, W. Oliver, K. Koshino, Y. Nakamura, J. S. Tsai, T. Yamamoto. Single-shot readout of a superconducting flux qubit with a flux-driven josephson parametric amplifier. Applied Physics Letters, 103:132602,2013.
[2] S. Uchaikin, J. Kim, C. Kutlu, B. Ivanov. Josephson parametric amplifer based quantum noise limited amplifier development for axion search experiments in capp. Frontiers in Physics, 12:1437680, 2024.
[3] T. Yamamoto, K. Inomata, M. Watanabe, K. Matsuba, T. Miyazaki, W. D. Oliver, Y.Nakamura, J. S. Tsai. Flux-driven josephson parametric amplifer. Applied Physics Letters, 93:042510, 2008.
[4] T. Elo, T.S. Abhilash, M. R. Perelshtein, I Lilja, E. V. Korostylev, P. J.Hakonen. Broadband lumped-element josephson parametric amplifier with single-step lithography. Applied Physics Letters, 112:252601, 2018.
[5] J. Y. Mtus, T. C. White, E. Jeffrey, D. Sank, R. Barends, J. Bochmann, Yu Chen, Z. Chen, B. Chiaro, A. Dunsworth, others. Design and characterization of a lumped element single-ended superconducting microwave parametric amplifier with on-chip fux bias line. Applied Physics Letters, 103:122602, 2013.
[6] T. W. Hu. Realization and characterization of a lumped-element josephson parametric amplifier. Master's thesis, National Central University, 2025.
[7] R. Kaufman, T. White, M. I. Dykman, A. Iorio, G. Sterling, S. Hong, A. Opremcak, A. Bengtsson, L. Faoro, J. C. Bardin, T. Burger, R. Gasca, O. Naaman. Josephson parametric amplifier with chebyshev gain profle and high saturation. Physical Review Applied, 20:054058, 2023.
[8] C. Eichler , A. Wallraff. Controlling the dynamic range of a josephson parametric amplifer. EPJ Quantum Technology, 2014.
[9] D. Arweiler. Multi-squid josephson parametric amplifiers. Master's thesis, Technical University of Munich, 2018. Master's Thesis.
[10] T. C. White, J. Y. Mutus, I-C Hoi, R. Barends, B. Campbell, Yu Chen, Z. Chen, B. Chiaro, A. Dunsworth, E. Jeffrey, others. Traveling wave parametric amplifier with josephson junctions using minimal resonator phase matching, Applied Physics Letters, 106:242601, 2015.
[11] Y. Kim, J. Jeong, S. Youn, S. Bae, A. F.van Loo, Y. Nakamura, S. Uchaikin, Y. K. Semertzidis. Parameter optimization of josephson parametric amplifiers us-
ing a heuristic search algorithm for axion haloscope search. Electronics, 13:212712127, 2024.
[12] Keysight Technologies. S-parameter measurements: Basics for high-speed digital engineers. Technical report, Keysight Technologies, 2019.
[13] R. Yang, H. Deng. Fabrication of the impedance-matched Josephson parametric ampliffer and the study of the gain profile. arXiu preprint, 1909.00707, 2019.
[14] National Instruments. What is labview?, 2023.