Real-Time Wind Field Estimation and Pitot Tube Calibration Using an Extended Kalman Filter

Zhang, Qian; Xu, Yifan; Wang, Xueyun; Yu, Zelong; Deng, Tianyi

doi:10.3390/math9060646

Cited by 17 publications

(10 citation statements)

References 24 publications

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“…As shown in Table 6, the relative error that affected airspeed measurements was found to be less than 9% in all the test scenarios considered, or less than 5% if we excluded test case 4 shown in Table 6, relative to a nonrealistic value of the AOA (which was typically in the range of −2 • to 15 • ). The estimation errors of α, β, and V CAS were found to be within 1.7 • (excluding the nonrealistic case α = 45 • ), 0.5 • , and 1.4 m/s, respectively, in good agreement with the theoretical values derived from the law of error propagation, and consistent with other authors' work [15,19,20,26]. The proposed approach showed a promising potentiality for implementation of real-time control laws to increase the flight envelope by exploiting attitude measurements and direct knowledge of α and β.…”

Section: Conclusion and Further Worksupporting

confidence: 90%

“…The sensors used in this research are a differential pressure sensor and a 10 degrees of freedom (DoF) inertial measurement unit (IMU), both managed by a microcontroller Arduino for data acquisition and TAS, AOA, and AOS estimation. We used 1D Kalman filtering to estimate and remove measurement noise, and complementary filtering was used to provide an estimate of the attitude from IMU acceleration and angular rate data [25,26]. Indoor sessions were needed for system setup and calibration.…”

Section: Introductionmentioning

confidence: 99%

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Estimation of Airspeed, Angle of Attack, and Sideslip for Small Unmanned Aerial Vehicles (UAVs) Using a Micro-Pitot Tube

Ariante¹,

Ponte²,

Papa³

et al. 2021

Electronics

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Fixed and rotary-wing unmanned aircraft systems (UASs), originally developed for military purposes, have widely spread in scientific, civilian, commercial, and recreational applications. Among the most interesting and challenging aspects of small UAS technology are endurance enhancement and autonomous flight; i.e., mission management and control. This paper proposes a practical method for estimation of true and calibrated airspeed, Angle of Attack (AOA), and Angle of Sideslip (AOS) for small unmanned aerial vehicles (UAVs, up to 20 kg mass, 1200 ft altitude above ground level, and airspeed of up to 100 knots) or light aircraft, for which weight, size, cost, and power-consumption requirements do not allow solutions used in large airplanes (typically, arrays of multi-hole Pitot probes). The sensors used in this research were a static and dynamic pressure sensor (“micro-Pitot tube” MPX2010DP differential pressure sensor) and a 10 degrees of freedom (DoF) inertial measurement unit (IMU) for attitude determination. Kalman and complementary filtering were applied for measurement noise removal and data fusion, respectively, achieving global exponential stability of the estimation error. The methodology was tested using experimental data from a prototype of the devised sensor suite, in various indoor-acquisition campaigns and laboratory tests under controlled conditions. AOA and AOS estimates were validated via correlation between the AOA measured by the micro-Pitot and vertical accelerometer measurements, since lift force can be modeled as a linear function of AOA in normal flight. The results confirmed the validity of the proposed approach, which could have interesting applications in energy-harvesting techniques.

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Section: Conclusion and Further Worksupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Estimation of Airspeed, Angle of Attack, and Sideslip for Small Unmanned Aerial Vehicles (UAVs) Using a Micro-Pitot Tube

Ariante¹,

Ponte²,

Papa³

et al. 2021

Electronics

View full text Add to dashboard Cite

show abstract

“…In the middle phase of UAV flight, the flight state is controlled based on the flight speed, specifically the airspeed value. Common methods for measuring the UAV airspeed include a pitot tube velocity measurement [ 15 , 16 , 17 , 18 ], integrated GPS with low-cost inertial navigation systems (IMU), and others [ 19 , 20 , 21 , 22 ]. For UAVs where precision in airspeed measurement is not crucial, the high cost of integrating GPS with IMU can be prohibitive.…”

Section: Introductionmentioning

confidence: 99%

Research on UAV Flight Parameter Identification Method Based on Launch Force and Airspeed

Chen,

Li,

et al. 2024

Sensors

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Flight parameters are crucial criteria for UAV control, playing a significant role in ensuring the safe and efficient completion of missions. Launch force and airspeed information are key parameters in the early and middle stages of flight, serving as important data for monitoring the UAV’s flight status. In response to challenges such as weak launch force, low identification rates, small airspeed, and low recognition accuracy in UAVs, a method for identifying UAV flight parameters based on launch force and airspeed is proposed. From the aspect of launch force identification, a recognition method based on a low-g value accelerometer information source is proposed, utilizing a ‘multi-level time window + threshold’ approach. For airspeed identification, an optimization method for airspeed measurement under the Kalman filter architecture is introduced. A device for airspeed measurement based on pressure sensors is designed, and the recommended installation position is determined through simulation. Furthermore, the feasibility and robustness of the proposed launch force identification and airspeed measurement optimization methods are validated through simulation. Finally, the effectiveness of the design is verified through centrifuge and wind tunnel experiments. This research provides technical support for the identification of the launch force and airspeed measurement in UAVs.

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“…It serves as a vital indicator for UAV control, enabling functions such as navigation, positioning, flight performance monitoring, maintaining flight stability, and enhancing flight safety. Common methods for measuring airspeed in UAVs include Pitot tube velocity measurements [1][2][3][4] and integrated Global Positioning System (GPSs) with low-cost Inertial Measurement Unit (IMU) [5][6][7][8] . For small UAVs with lower cost and less stringent airspeed measurement requirements, GPS and IMU strategies can be expensive.…”

Section: Introductionmentioning

confidence: 99%

Designing of Airspeed Measurement Method for UAV Based on MEMS Pressure Sensors

chen,

Li,

et al. 2024

Preprint

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Airspeed measurement is crucial for UAV control. To achieve accurate airspeed measurements for UAV, this paper calculates airspeed data by measuring changes in air pressure and temperature. Based on this, a data processing method based on mechanical filtering and improved AR-SHAKF algorithm is proposed to indirectly measure airspeed with high precision. In particular, a mathematical model for an airspeed measurement system is established, and an installation method for the pressure sensor is designed to measure the total pressure, static pressure and temperature. Secondly, the measurement principle of the sensor are analyzed, and a metal tube is installed to act as a mechanical filter, particularly in cases where the aircraft has a significant impact on the gas flow field. Furthermore, a time-series model is used to establish the sensor state equation and the initial noise values. It also enhances the Sage-Husa adaptive filter to analyze the unavoidable error impact of initial noise values. By constraining the range of measurement noise, it achieves adaptive noise estimation. To validate the superiority of the proposed method, a low-complexity airspeed measurement device based on MEMS pressure sensors is designed. The results demonstrate that the airspeed measurement device and the designed velocity measurement method can effectively calculate airspeed with high measurement accuracy and strong interference resistance.

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Real-Time Wind Field Estimation and Pitot Tube Calibration Using an Extended Kalman Filter

Cited by 17 publications

References 24 publications

Estimation of Airspeed, Angle of Attack, and Sideslip for Small Unmanned Aerial Vehicles (UAVs) Using a Micro-Pitot Tube

Estimation of Airspeed, Angle of Attack, and Sideslip for Small Unmanned Aerial Vehicles (UAVs) Using a Micro-Pitot Tube

Research on UAV Flight Parameter Identification Method Based on Launch Force and Airspeed

Designing of Airspeed Measurement Method for UAV Based on MEMS Pressure Sensors

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