Paper | Title | Other Keywords | Page |
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MO4BCO05 | Apples to Oranges: A Comparison of EPICS Build and Deployment Systems | EPICS, site, controls, MMI | 205 |
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ESS currently uses two different systems for managing the build and deployment of EPICS modules. Both of these use modules that are packaged and prepared to be dynamically loaded into soft IOCs, based on the require module developed at PSI. The difference is the deployment: For the accelerator, we use a custom utility to define and build an EPICS environment which is then distributed on a global shared filesystem to the production and lab networks. For the neutron instrumentation side, in contrast, we use conda to build individual EPICS environments for each IOC, where the underlying packages are stored on a shared artifactory server. In each case, the goal is to provide a repeatable and controllable mechanism to produce a consistent EPICS environment for IOCs in use at ESS. The difference (other than the tools and storage) is in some sense philosophical: should a software environment be defined at build-time or at run-time? In this presentation we will provide an overview of some of the challenges, contrasts, and lessons learned from these two different but related approaches to EPICS module deployment. | |||
Slides MO4BCO05 [0.819 MB] | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-MO4BCO05 | ||
About • | Received ※ 06 October 2023 — Accepted ※ 13 October 2023 — Issued ※ 24 October 2023 | ||
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TU2AO02 | Textual Analysis of ICALEPCS and IPAC Conference Proceedings: Revealing Research Trends, Topics, and Collaborations for Future Insights and Advanced Search | cavity, cryogenics, controls, laser | 309 |
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Funding: This work was supported by HamburgX grant LFF-HHX-03 to the Center for Data and Computing in Natural Sciences (CDCS) from the Hamburg Ministry of Science, Research, Equalities and Districts. In this paper, we show a textual analysis of past ICALEPCS and IPAC conference proceedings to gain insights into the research trends and topics discussed in the field. We use natural language processing techniques to extract meaningful information from the abstracts and papers of past conference proceedings. We extract topics to visualize and identify trends, analyze their evolution to identify emerging research directions and highlight interesting publications based solely on their content with an analysis of their network. Additionally, we will provide an advanced search tool to better search in the existing papers to prevent duplication and easier reference findings. Our analysis provides a comprehensive overview of the research landscape in the field and helps researchers and practitioners to better understand the state-of-the-art and identify areas for future research. |
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Slides TU2AO02 [12.762 MB] | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TU2AO02 | ||
About • | Received ※ 30 September 2023 — Revised ※ 11 October 2023 — Accepted ※ 18 November 2023 — Issued ※ 29 November 2023 | ||
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TUMBCMO30 | EPICS Based Tool for LLRF Operation Support and Testing | cavity, controls, EPICS, operation | 432 |
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Interruptions in the functioning of linear superconductive accelerators LLRF (Low-Level Radio Frequency) systems can result in significant downtime. This can lead to lost productivity and revenue. Accelerators are foreseen to operate under various conditions and in different operating modes. As such, it is crucial to have flexibility in their operation to adapt to demands. Automation is a potential solution to address these challenges by reducing the need for human intervention and improving the control’s quality over the accelerator. The paper describes EPICS-based tools for LLRF control system testing, optimization, and operations support. The proposed software implements procedures and applications that are usually extensions to the core LLRF systems functionalities and are performed by operators. This facilitates the maintenance of the accelerator and increases its flexibility in adaptation to various work conditions and can increase its availability level. The paper focuses on the architecture of the solution. It also depicts its components related to superconducting cavities parameters identification and elements responsible for their tuning. Since the proposed solution is destined for the European Spallation Source control system, the application has a form of multiple IOCs (Input/Output Controllers) wrapped into E3 (ESS EPICS Environment) modules. Nevertheless, it can be adjusted to other control systems - its logic is universal and applicable (after adaptations) to other LLRF control systems with superconducting cavities. | |||
Slides TUMBCMO30 [0.466 MB] | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUMBCMO30 | ||
About • | Received ※ 06 October 2023 — Revised ※ 12 October 2023 — Accepted ※ 28 November 2023 — Issued ※ 30 November 2023 | ||
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TUPDP136 | Control Systems Design for STS Accelerator | controls, timing, operation, target | 903 |
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Funding: This manuscript has been authored by UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). The Second Target Station (STS) Project will expand the capabilities of the existing Spallation Neutron Source (SNS), with a suite of neutron instruments optimized for long wavelengths. A new accelerator transport line will be built to deliver one out of four SNS pulses to the new target station. The Integrated Control Systems (ICS) will provide remote control, monitoring, OPI, alarms, and archivers for the accelerator systems, such as magnets power supply, vacuum devices, and beam instrumentation. The ICS will upgrade the existing Linac LLRF controls to allow independent operation of the FTS and STS and support different power levels of the FTS and STS proton beam. The ICS accelerator controls are in the phase of preliminary design for the control systems of magnet power supply, vacuum, LLRF, Timing, Machine protection system (MPS), and computing and machine network. The accelerator control systems build upon the existing SNS Machine Control systems, use the SNS standard hardware and EPICS software, and take full advantage of the performance gains delivered by the PPU Project at SNS. |
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Poster TUPDP136 [2.403 MB] | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-TUPDP136 | ||
About • | Received ※ 27 September 2023 — Revised ※ 09 October 2023 — Accepted ※ 13 October 2023 — Issued ※ 22 October 2023 | ||
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THPDP041 | The RF Protection Interlock System Prototype Verification | FPGA, diagnostics, interface, software | 1406 |
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The Radio Frequency Protection Interlock system plays vital role in the LLRF related/dependent accelerator sections Protection. It’s main role is to collect information from number different sensors and indicators around nearest cavities and cryomodule and provide instant RF signal termination in case of safety thresholds violation. This submission describes newly designed RFPI system tailored to the Proton Improvement Plan II (PIP-II) requirements. The proof of concept prototype of this system has been build. The paper includes also the CMTF environment evaluation tests results and findings as an input to the next full-scope prototype design. | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-THPDP041 | ||
About • | Received ※ 06 October 2023 — Revised ※ 26 October 2023 — Accepted ※ 08 December 2023 — Issued ※ 13 December 2023 | ||
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THPDP051 | LLRF and Timing System Integration at ESS | timing, controls, cavity, MMI | 1426 |
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The Low Level Radio Frequency (LLRF) system is an important part of a Spallation Source facility as ESS. LLRF is commonly used with many different setups depending on the aim: preparation, calibration, conditioning, commission and others. These different setups are strongly connected to another important system on accelerators: the Timing System. This proceeding presents how at ESS we implemented the integration between LLRF and Timing systems on the control system scope. The integration of these two systems provides different and important features as: allow different ways to trigger the RF system (synced or not to other systems), define how the RF output will be defined (based on the features of the expected beam), re-configure LLRF depending on the timing setup and more. This integration was developed on both ends, LLRF and timing, and is mostly concentrated on the control system layer based on EPICS. Dealing with the different scenarios, synchronicity and considering all the software, hardware and firmware involved are some of the challenges of this integration. The result of this work was used during the ESS accelerator commissioning in 2022 and will be used on next ESS accelerator commissioning in 2023. | |||
Poster THPDP051 [0.993 MB] | |||
DOI • | reference for this paper ※ doi:10.18429/JACoW-ICALEPCS2023-THPDP051 | ||
About • | Received ※ 05 October 2023 — Accepted ※ 08 December 2023 — Issued ※ 12 December 2023 | ||
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