Evoluation of the Malta2 readout firmware to ultrascale and evaluation for itk replacement in atlas
| dc.contributor.author | Işık, Fuat Kerem | |
| dc.date.accessioned | 2026-07-17T07:20:27Z | |
| dc.date.issued | 2026 | |
| dc.description.abstract | This thesis presents the evolution of the MALTA2 monolithic active pixel sensor readout firmware to a Kintex UltraScale architecture using the ALINX AXKU040 development board. The work was motivated by the need for a sustainable long-term readout platform for MALTA2 laboratory measurements, beam-test applications, and ATLAS ITk-based high-rate studies, while preserving compatibility with the established DAQ software inter face. Rather than being a direct board migration, the firmware was revised to improve the external readout chain. The main developments include an optimized asynchronous over sampling data path for nanosecond-scale sensor outputs, updated delay and deserialization resources, an Ethernet interface adapted to the target board, a simplified slow-control path, and a hardware-assisted injection pulse-generation scheme. FPGA implementation results and comparative measurements with the previous KC705-based system confirm that the upgraded firmware preserves the required readout behavior while improving samplingsta bility, full-matrix response uniformity, and scan execution time. In representative analog scan measurements,theupgradedreadoutreducesreadout-relatedspatial non-uniformities across the full pixel matrix, increasing the fraction of pixels measured within 5% of the ex pected response from about 77% to nearly 100%. The improved injection-control scheme reduces scan execution times by up to approximately a factor of two, which is especially important for extended threshold-scan measurements. An additional ATLAS ITk-based high-rate simulation study relates the MALTA2 response to realistic occupancy bench mark conditions. Overall, the upgraded UltraScale readout establishes a more reliable, faster, and maintainable framework for continued MALTA2 operation and future MALTA readout developments.firmware preserves the required readout behavior while improving samplingsta bility, full-matrix response uniformity, and scan execution time. In representative analog scan measurements,theupgradedreadoutreducesreadout-relatedspatial non-uniformities across the full pixel matrix, increasing the fraction of pixels measured within 5% of the ex pected response from about 77% to nearly 100%. The improved injection-control scheme reduces scan execution times by up to approximately a factor of two, which is especially important for extended threshold-scan measurements. An additional ATLAS ITk-based high-rate simulation study relates the MALTA2 response to realistic occupancy bench mark conditions. Overall, the upgraded UltraScale readout establishes a more reliable, faster, and maintainable framework for continued MALTA2 operation and future MALTA readout developments. | |
| dc.identifier.uri | http://hdl.handle.net/20.500.12575/93948 | |
| dc.language.iso | en | |
| dc.publisher | Ankara Üniversitesi | |
| dc.subject | Particle tracking detectors | |
| dc.subject | monolithic active pixel sensors | |
| dc.subject | detector readout | |
| dc.subject | FPGAfirmware | |
| dc.subject | data acquisition | |
| dc.subject | ATLAS ITk-based studies | |
| dc.title | Evoluation of the Malta2 readout firmware to ultrascale and evaluation for itk replacement in atlas | |
| dc.title.alternative | Malta2 okuma aygıt yazılımının ultrascale’e evrimi ve atlas’ta ıtk’nin yerini alması açısından değerlendirilmesi | |
| dc.type | Thesis |
