OAR@UM Collection:/library/oar/handle/123456789/1042422025-11-09T08:51:24Z2025-11-09T08:51:24ZInnovative power conditioning and interfacing circuitry for various energy harvesting devices/library/oar/handle/123456789/1044262022-12-15T08:45:12Z2022-01-01T00:00:00ZTitle: Innovative power conditioning and interfacing circuitry for various energy harvesting devices
Abstract: This research work focuses on the design, implementation, fabrication
and characterisation of a novel power conditioning integrated circuit
proposed for capturing maximal energy from a wide range of energy
devices. The proposed power conditioning circuit has a wide input
voltage range and power range and employs a maximum power point
tracking circuit to operate the energy harvesting device at maximum
power at any operating condition. A direct AC/DC-to-DC converter
makes this power conditioning circuit compatible with harvesters
generating both AC or DC output voltages without the need of external
rectification. Energy storage is provided by means of a high storage
capacitor which reduces the down time of the load and stores any
excess power being generated by the energy harvester. The final stage
of the conditioning circuit is a hysteretic controlled buck converter
which generates an adjustable, clean, and constant output voltage as
required by the load. Both circuit stages were fabricated while requiring
a minimum number of external components.
In particular, the work undertaken and explained in this dissertation
can be classified into two main parts. The first part focuses on the
design, implementation, simulation, fabrication and characterisation of
a novel direct AC/DC-to-DC converter with MPPT function.
The second part focuses on the design, implementation, simulation,
fabrication and characterisation of a novel hysteretic controlled buck
converter integrated with on-chip bootstrapping circuit.
Description: Ph.D.(Melit.)2022-01-01T00:00:00ZFront-end readout electronics for the ALICE CPV and HMPID particle detectors/library/oar/handle/123456789/1043692022-12-14T08:48:33Z2022-01-01T00:00:00ZTitle: Front-end readout electronics for the ALICE CPV and HMPID particle detectors
Abstract: This work, carried out in collaboration with the European Council for Nuclear Research (CERN)
and the University of Malta, presents the development of a new electronic front-end readout
system for the High momentum particle identification (HMPID) and Charged Particle Veto
(CPV) detectors. The upgrade strategy of the A Large Ion Collider Experiment (ALICE) is based
on the collection of more than 10 nb-1 Pb-Pb collisions at a luminosity of 6x1027 cm-2
8 -1, corresponding to a collision rate of 50 kHz for Pb-Pb and 200 kHz for pp and p-Pb. The
requirements for such a high beam luminosity cannot be met with the existing CPV electronics,
which had a low readout rate of 5 kHz. The development of such a system is a challenging task.
Therefore, different technologies and architectural topologies were considered and investigated
for the optimization of the front-end readout electronics. This work contributed to the
development of a new custom front-end readout electronics system architecture for the CPV
detector module in the PHOton spectrometer (PHOS). This newly developed electronics were
commissioned and accepted by the Russian Institute of High Energy Physics and the ALICE
collaboration for installation in November 2020. Compared to previous systems, the proposed
new architecture allows parallel readout and processing of all 480 silicon photomultiplier pads
connected to digital signal processing boards. Optimization strategies include the use of 28 nm
FPGA technology with high pin count and low power consumption for simultaneous readout of
digital signal processors, referred to as 5 DIL boards, and the use of high-speed 3.125 Gbps
transceiver interconnects. In addition, the newly developed FPGA firmware architecture has
helped increase the event readout rate and data throughput by a factor of ten. This work enables
both the CPV and HMPID detectors to achieve an interaction rate of at least 50 kHz. The system
design consists of three modules, each containing two segment cards, two readout common
boards (RCBs), and 20 digital signal processors. Five processors are grouped on an electronic
board called 5- DIL board. This report presents the architectural layout and preliminary results
of performance measurements for the proposed new design. In addition, this work has
contributed to the development of a new ASIC chip that integrates four digital signal processors,
error correction and detection circuitry, and four serial transmitters with a bandwidth of at least
0.5 Gbps. The ASIC chip implementation uses XFAB-180-nm technology and is capable of
processing at least 192 analogue channels simultaneously. The developed ASIC device can be
easily integrated into current CPV and similar electronic readout circuits for physics particle
detectors, which helps reduce the required number of electronic components and PCB
manufacturing costs. This work concludes with recommendations for further planned updates to
the hardware scheme.
Description: Ph.D.(Melit.)2022-01-01T00:00:00Z