Journal of Systems Engineering and Electronics ›› 2026, Vol. 37 ›› Issue (2): 467-484.doi: 10.23919/JSEE.2026.000055
• DEFENCE ELECTRONICS TECHNOLOGY • Previous Articles
Dan LIU1,2, Yuzhe FAN1(
), Lin’gang FAN1,2,*(), Chengzeng CHEN2,3(), Yan DAI1,2()
Received:2024-11-27
Accepted:2025-03-28
Online:2026-04-18
Published:2026-04-30
Contact:
Lin’gang FAN
E-mail:786225944@qq.com;flg2004@163.com;chenchengzeng66@163.com;hitdy2012@126.com
About author:LIU Dan, photograph and biography not available at the time of publicationDan LIU, Yuzhe FAN, Lin’gang FAN, Chengzeng CHEN, Yan DAI. Attitude estimation of space target based on ISAR contour projection plane alignment[J]. Journal of Systems Engineering and Electronics, 2026, 37(2): 467-484.
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Fig 1
Algorithm flowchart"
Fig 2
Spatial coordinate system relationship diagram"
Fig 3
Matching results caused by rotation invariance"
Fig 4
Same projection corresponding to different image planes and attitudes"
Fig 5
Same projection corresponding to the same image plane and different attitudes"
Fig 6
Schematic diagram of determining the unique attitude using the minimum distance method"
Fig 7
Algorithm process of minimum distance method"
Fig 8
Typical space target model"
Fig 9
Radar LOS direction variation"
Fig 10
Matching results of five frames in scatter point imaging experiment"
Table 1
Multi frame joint solution for attitude results in scatter point imaging experiment (°)"
| Frame sequence | Match attitude 1 | Match attitude 2 | Match attitude 3 | Match attitude 4 | Match attitude 5 | Error |
| 1st frame | (−73.1,64.3,−62.3) | (−26.2,−20.0,−125.6) | (26.2,20.0,54.4) | (73.1,−64.3,117.7) | (−16.2,−20.0,−125.6) | 6.6 |
| 2nd frame | (62.2,−1.2,87.4) | (73.4,−56.8,112.0) | (−73.4,56.8,−68.0) | (−62.2.1.2,−92.6) | (49.6,−5.0,92.6) | 7.9 |
| 3rd frame | (98.3,−4.4,104.0) | (71.4,−63.2,110.1) | (−86.0,53.6,−75.3) | (−88.5,14.3,−77.5) | (−81.4,63.2,−69.9) | 12.1 |
| 4th frame | (125.3,−7.2,120.4) | (80.5,−57.5,107.3) | (113.4,−5.5,125.1) | (85.7,−60.9,114.4) | (115.3,−7.2,120,4) | 5.4 |
| 5th frame | (155.0,11.0,148.0) | (85.5,−65.4,103.9) | (145.0,11.0,148.0) | (95.5,−65.4,103.9) | (147.8,−1.2,146.6) | 7.9 |
Table 2
Comparison results of three methods in scatter point imaging experiment"
| Method | Error in attitude 1/( | Error in attitude 2/( | Error in attitude 3/( | Average time/s |
| Method in this paper | 1.4 | 1.6 | 2.1 | 130 |
| Shape context matching method | 4.1 | 3.2 | 4.7 | 292 |
| Projection energy method | 2.9 | 3.3 | 6.1 | 205 |
Fig 11
Relationship between error and SNR in scatter point imaging experiment"
Fig 12
Matching results of five frames in electromagnetic simulation imaging experiment"
Table 3
Multi frame joint solution for attitude results in electromagnetic simulation imaging experiment (°)"
| Frame sequence | Match attitude 1 | Match attitude 2 | Match attitude 3 | Match attitude 4 | Match attitude 5 | Error |
| 1st frame | (26.2,20.0,54.4) | (73.1,−64.3,117.7) | (−72.6,56.1,−67.4) | (−33.6,−15.7,−117.7) | (82.6,−56.1,112.6) | 3.6 |
| 2nd frame | (52.2,−1.2,87.4) | (54.5,1.9,81.8) | (−73.4,56.8,−68.0) | (84.7,−62.9,107.8) | (−62.2,1.2,−92.6) | 4.4 |
| 3rd frame | (88.2,−24.6,102.7) | (87.1,−15.0,106.0) | (88.5,−14.3,102.5) | (88.3,−4.4,104.0) | (86.0,−53.6,104.7) | 6.8 |
| 4th frame | (55.7,−60.9,114.4) | (−133.5,5.5,−54.9) | (135.3,−7.2,120.4) | (70.5,−57.5,107.3) | (−58.6,63.2,−56.1) | 14.7 |
| 5th frame | (147.5,7.3,141.2) | (92.2,−57.8,103.6) | (155.0,11.0,148.0) | (85.5,−65.4,103.9) | (−92.2,57.8,−76.4) | 7.9 |
Fig 13
Relationship between the ranking of true attitude and SNR"
Table 4
Comparison results of four methods in electromagnetic simulation imaging experiment"
| Methods | Error in attitude 1/( | Error in attitude 2/( | Error in attitude 3/( | Average time/s |
| Method in this paper | 2.1 | 2.5 | 2.4 | 125 |
| Shape context matching method | 4.6 | 5.8 | 4.9 | 285 |
| Projection energy method | 4.9 | 4.6 | 6.7 | 223 |
| Line feature method | 2.2 | 2.2 | 2.3 | 19 |
Fig 14
Single sailboard satellite model"
Table 5
Comparison results of two methods in single sailboard target experiment"
| Methods | Error in attitude 1/( | Error in attitude 2/( | Error in attitude 3/( | Average time/s |
| Method in this paper | 2.6 | 2.5 | 3.2 | 128 |
| Line feature method | 16.2 | 22.9 | 18.5 | 21 |
Fig 15
Feature extraction of single sailboard satellite"
Fig 16
Relationship between error and observation duration in electromagnetic simulation imaging experiment"
Fig 17
Selection of different imaging periods"
Table 6
Comparison results of four methods in imaging periods experiment"
| Methods | Error in imaging period 1/( | Error in imaging period 2/( | Error in imaging period 3/( |
| Method in this paper | 7.4 | 7.8 | 15.5 |
| Shape context matching method | 11.3 | 9.5 | 16.9 |
| Projection energy method | 11.9 | 12.3 | 18.0 |
| Line feature method | 8.3 | 9.7 | 27.7 |
Fig 18
Relationship between error and refractivity in electromagnetic simulation imaging experiment"
Fig 19
Relationship between error and resolution in electromagnetic simulation in electromagnetic simulation imaging experiment"
Fig 20
Relationship between error and SNR in electromagnetic simulation imaging experiment"
Fig 21
Contour extraction results at different resolutions"
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