Health Indicator Degradation Dataset 核心 · 已核验

doi:10.5281/zenodo.20647258

To be representative of realistic problem configuration, the degradation trajectories scenarios are designed by taking into account the following considerations. Generally, the turbofan engines may degrade gradually over time based on different conditions, usage and maintenance operations performed during their lifetime. The degradation speed may also change with respect to these conditions and regarding the different components in the engine. For example the high pressure compressor degrades faster than the other components, as it is exposed to much higher temperature than the other components. In this sense, each degradation trajectory S represents a multivariate time series of dimension 10 (number of health indicators corresponding to different components of the engine). Each component of the engine has its own specific degradation pattern and boundaries (minimum and maximum authorized values). Three different degradation speeds (i.e., slow, normal and fast) are considered. The components may degrade following a probability distribution over the three speed values and also to transition from one speed to another with a specific frequency (e.g., every 100 timesteps). Maintenance operations could also take place after certain time steps, picking a random value within the interval [200;500]. The maintenance events allow to partially recover the previous health state, which is controlled by a coefficient selected randomly in the interval [0.6;0.8]. The dataset is organized in a csv file with a header designating the name of columns. The first column is the sequence ID. There are more than 500 sequences with different lengths. The columns include 10 health indicators ('deg_CmpBst_s_mapEff_in', 'deg_CmpBst_s_mapWc_in', 'deg_CmpFan_s_mapEff_in', 'deg_CmpFan_s_mapWc_in', 'deg_CmpH_s_mapEff_in', 'deg_CmpH_s_mapWc_in', 'deg_TrbH_s_mapEff_in', 'deg_TrbH_s_mapWc_in', 'deg_TrbL_s_mapEff_in', 'deg_TrbL_s_mapWc_in'), timestep for each sequence 3 generation-based parameters ('maintenance', 'speed_change', 'speed_strategy') Sensor measurements and operational conditions for each flight phase (i.e., Cruise, Takeoff, Climb1, Climb2) These variables are ('PHASE_DeckSMR__HPC_Tout', 'PHASE_DeckSMR__HP_Nmech', 'PHASE_DeckSMR__HPC_Tin', 'PHASE_DeckSMR__LPT_Tin', 'PHASE_DeckSMR__Fuel_flow', 'PHASE_DeckSMR__HPC_Pout_st', 'PHASE_DeckSMR__LP_Nmech'), where PHASE is one the above-mentioned flight phases. In the inverse problem introduced in the article, we try to predict the 10 health indicators from 28 (4x7) sensor measurements. Where we have four flight phases and seven sensor measurements. The operational conditions ('Cruise_DeckSMR__DTAMB', 'Cruise_DeckSMR__ALT', 'Cruise_DeckSMR__COMMAND', 'Cruise_DeckSMR__MACH', 'Cruise_DeckSMR__Convergence') are considered as constant in this study, but could also evolve in future. Use the following python code to reorganize the data as sequences: import pandas as pd import numpy as np file_name = "2000_aligned_and_clean_indexfalse.csv" df = pd.read_csv(file_name) values = ( df .groupby("sequence_id")[list(df.columns[1:])] .apply(lambda x: x.to_numpy()) .to_list() ) sequences = np.array(values, dtype="O")(Zenodo 记录 20647259 自述,2026-07-15 核)

落地页
https://zenodo.org/records/20647259
许可证
CC-BY-4.0 (判读置信:verified_official)
国内可访问性
国内直连:直连超时(慢或不稳定,非封锁证据) (2026-07-11 检测) 代理通道:可达 (2026-07-11 检测)
检测口径:lychee 双通道单轮探测;「直连超时」表示检测窗口内未完成,系慢或不稳定证据,不构成封锁证据。
设备类型
aero_engine
PHM 任务
degradation_trend_prediction
溯源(PROV,6 条)
source_url: https://zenodo.org/doi/10.5281/zenodo.20647259source_citation: mech_oam_hub datasets#526(canonical_key=doi:10.5281/zenodo.20647258)retrieved_on: 2026-07-09asserted_by: automated_harvestnote: 采石场迁移候选;原 review_status=auto(自动晋升,非人工核验)
about_field: china_accessibilitysource_citation: KLS-009 链接健康扫描(lychee 双通道)retrieved_on: 2026-07-12asserted_by: automated_harvestnote: 定期刷新标注,仅覆盖本字段;历史结果以最新扫描为准
about_field: equipment_types,landing_page,license_confidence,notes,taskssource_citation: 人工核验:zfbin(委托批次 KLS-033-A,2026-07-15)retrieved_on: 2026-07-15asserted_by: human_curatorconfidence_level: human_verifiednote: 人工改写。KLS-033 细读(涡扇 HI 零刻面卡):Zenodo API(records/20647259)自述+关键词(Turbofan engine health monitoring/Realistic simulation data)核验;描述清理 HTML 实体,landing 归一 records URL,SPDX 大小写归一;历史置信值 inferred 无溯源覆盖一并撤除(修复③重登)
about_field: description,license_idsource_citation: 人工核验:zfbin(委托批次 KLS-033-A,2026-07-15)retrieved_on: 2026-07-15asserted_by: human_curatorconfidence_level: human_verifiednote: 人工改写。KLS-033 覆盖修复①:描述追加来源注记(对 Zenodo 记录逐句核过);历史 license_id 值正确但无溯源覆盖,撤除待核验重登(判例同批次 09/本批 cold 卡)
about_field: source_citation: 人工核验:zfbin(委托批次 KLS-033-A,2026-07-15)retrieved_on: 2026-07-15asserted_by: human_curatorconfidence_level: human_verifiednote: 晋升核心区。KLS-033-A:Zenodo 自述逐断言核验(涡扇 HI 仿真退化,刻面自述直接支持)
about_field: license_confidence,license_idsource_citation: 人工核验:zfbin(委托批次 KLS-033-A,2026-07-15)retrieved_on: 2026-07-15asserted_by: human_curatorconfidence_level: human_verifiednote: 人工改写。KLS-033 覆盖修复③:按 Zenodo API(records/20647259)license 字段核验 CC-BY-4.0(2026-07-15)重新登记 license_id + 置信 verified_official