Title :
Design of eight-channel ADC card for GHz signal conversion
Author :
Habib, Samer Bou ; Czuba, Krzysztof ; Jalmuzna, Wojciech ; Jezynski, Tomasz
Author_Institution :
Insitute of Electron. Syst., Warsaw Univ. of Technol., Warsaw, Poland
Abstract :
This paper describes the design of an eight-channel ATCA card suited for direct analog-to-digital conversion of 1.3 GHz signals with a maximum ADC clock frequency of 500 MHz. The undersampling operation is used for signal conversion. This card was designed for the needs of the LLRF system of the FLASH and XFEL accelerators. The designed module consists of a main ATCA board with eight ADCs, FPGA unit, memory, power supply and diagnostic circuits. The main ATCA card allows connecting a daughter board with IPMI, CPU and fast interfaces for communication purposes. This paper describes such issues as system organization allowing acquisition of data at such high data rates, circuit synchronization by high-quality clock signals, CPU and connectivity features, 20-layer PCB design and techniques used for high-frequency signals transmission and matching.
Keywords :
analogue-digital conversion; data acquisition; field programmable gate arrays; signal sampling; 20-layer PCB design; ATCA board; ATCA card; CPU; FLASH accelerators; FPGA unit; IPMI; LLRF system; XFEL accelerators; circuit synchronization; clock frequency; data acquisition; data rates; diagnostic circuits; direct analog-to-digital conversion; eight-channel ADC card design; frequency 1.3 GHz; frequency 500 MHz; high-quality clock signals; power supply circuits; signal conversion; signal matching; signal transmission; undersampling operation; Clocks; Field programmable gate arrays; Frequency measurement; Jitter; Radio frequency; Receivers; Synchronization; ATCA; LLRF; direct sampling; fast ADC; field detection;
Conference_Titel :
Mixed Design of Integrated Circuits and Systems (MIXDES), 2010 Proceedings of the 17th International Conference
Conference_Location :
Warsaw
Print_ISBN :
978-1-4244-7011-2
Electronic_ISBN :
978-83-928756-4-2
