- Main
Ionization electron signal processing in single phase LArTPCs. Part I. Algorithm Description and quantitative evaluation with MicroBooNE simulation
- Adams, C;
- An, R;
- Anthony, J;
- Asaadi, J;
- Auger, M;
- Bagby, L;
- Balasubramanian, S;
- Baller, B;
- Barnes, C;
- Barr, G;
- Bass, M;
- Bay, F;
- Bhat, A;
- Bhattacharya, K;
- Bishai, M;
- Blake, A;
- Bolton, T;
- Camilleri, L;
- Caratelli, D;
- Fernandez, R Castillo;
- Cavanna, F;
- Cerati, G;
- Chen, H;
- Chen, Y;
- Church, E;
- Cianci, D;
- Cohen, E;
- Collin, GH;
- Conrad, JM;
- Convery, M;
- Cooper-Troendle, L;
- Crespo-Anadón, JI;
- Del Tutto, M;
- Devitt, D;
- Diaz, A;
- Dytman, S;
- Eberly, B;
- Ereditato, A;
- Sanchez, L Escudero;
- Esquivel, J;
- Evans, JJ;
- Fadeeva, AA;
- Fleming, BT;
- Foreman, W;
- Furmanski, AP;
- Garcia-Gamez, D;
- Garvey, GT;
- Genty, V;
- Goeldi, D;
- Gollapinni, S;
- Gramellini, E;
- Greenlee, H;
- Grosso, R;
- Guenette, R;
- Guzowski, P;
- Hackenburg, A;
- Hamilton, P;
- Hen, O;
- Hewes, J;
- Hill, C;
- Ho, J;
- Horton-Smith, GA;
- Hourlier, A;
- Huang, E-C;
- James, C;
- de Vries, J Jan;
- Jiang, L;
- Johnson, RA;
- Joshi, J;
- Jostlein, H;
- Jwa, Y-J;
- Kaleko, D;
- Karagiorgi, G;
- Ketchum, W;
- Kirby, B;
- Kirby, M;
- Kobilarcik, T;
- Kreslo, I;
- Li, Y;
- Lister, A;
- Littlejohn, BR;
- Lockwitz, S;
- Lorca, D;
- Louis, WC;
- Luethi, M;
- Lundberg, B;
- Luo, X;
- Marchionni, A;
- Marcocci, S;
- Mariani, C;
- Marshall, J;
- Caicedo, DA Martinez;
- Mastbaum, A;
- Meddage, V;
- Miceli, T;
- Mills, GB;
- Mogan, A;
- Moon, J;
- Mooney, M;
- Moore, CD;
- Mousseau, J;
- Murphy, M;
- Murrells, R;
- Naples, D;
- Nienaber, P;
- Nowak, J;
- Palamara, O;
- Pandey, V;
- Paolone, V;
- Papadopoulou, A;
- Papavassiliou, V;
- Pate, SF;
- Pavlovic, Z;
- Piasetzky, E;
- Porzio, D;
- Pulliam, G;
- Qian, X;
- Raaf, JL;
- Radeka, V;
- Rafique, A;
- Rochester, L;
- Ross-Lonergan, M;
- von Rohr, C Rudolf;
- Russell, B;
- Schmitz, DW;
- Schukraft, A;
- Seligman, W;
- Shaevitz, MH;
- Sinclair, J;
- Smith, A;
- Snider, EL;
- Soderberg, M;
- Söldner-Rembold, S;
- Soleti, SR;
- Spentzouris, P;
- Spitz, J;
- St. John, J;
- Strauss, T;
- Sutton, K;
- Sword-Fehlberg, S;
- Szelc, AM;
- Tagg, N;
- Tang, W;
- Terao, K;
- Thomson, M;
- Thorn, C;
- Toups, M;
- Tsai, Y-T;
- Tufanli, S;
- Usher, T;
- Van De Pontseele, W;
- Van de Water, RG;
- Viren, B;
- Weber, M;
- Wei, H;
- Wickremasinghe, DA;
- Wierman, K;
- Williams, Z;
- Wolbers, S;
- Wongjirad, T;
- Woodruff, K;
- Yang, T;
- Yarbrough, G;
- Yates, LE;
- Yu, B;
- Zeller, GP;
- Zennamo, J;
- Zhang, C
- et al.
Published Web Location
https://doi.org/10.1088/1748-0221/13/07/p07006Abstract
We describe the concept and procedure of drifted-charge extraction developed in the MicroBooNE experiment, a single-phase liquid argon time projection chamber (LArTPC). This technique converts the raw digitized TPC waveform to the number of ionization electrons passing through a wire plane at a given time. A robust recovery of the number of ionization electrons from both induction and collection anode wire planes will augment the 3D reconstruction, and is particularly important for tomographic reconstruction algorithms. A number of building blocks of the overall procedure are described. The performance of the signal processing is quantitatively evaluated by comparing extracted charge with the true charge through a detailed TPC detector simulation taking into account position-dependent induced current inside a single wire region and across multiple wires. Some areas for further improvement of the performance of the charge extraction procedure are also discussed.
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