**Author details**

Tab.3. And the result of analysis is in Fig.26. As shown in Fig.26., the revised simulator could indicate roughly same value of amplitude of dynamic responses with consideration of

Temperatures of Top panel, Bottom panel, wires. Given by thermal model

When a satellite in Low Earth Orbit (LEO) goes through an eclipse, sudden changes in the thermal environment will occur. These sudden thermal changes caused by a difference in temperature between the Sun side and the opposite side of the satellite's solar array paddle. This temperature difference causes bending and then vibration of the solar array paddle. However, the bending and vibration amplitude are too small to be observed by convention‐ al satellite attitude sensors. To solve this problem, we used an onboard camera to directly measure solar paddle bending. The previously reported methods of observing the motion of the satellite's solar array paddle were not free from errors in image data processing, espe‐

This chapter paper described the improved image data processing algorism applied to measure bending and deformation of the satellite's solar array paddle that are believed to cause degraded satellite attitude stability, which occurs when the satellite goes into an eclipse. The revised observation data shows both quasi-static deformation and rapid dy‐ namic vibration in the penumbra. We also conducted numerical analysis to verify the ob‐ served data and understand the features of thermal snap on the solar array paddle. From this analysis, we found that sudden changes in solar array paddle temperature induce quasistatic deformation, and that the wires controlling solar array paddle deployment have a large influence on solar array paddle vibration. Additionally, we also found that a specific lower frequency vibration appearing in the penumbra can help to explain this vibration mechanism. Developing the detailed hinge model, we succeeded to simulate the vibration property change related to dynamical regime. Then, we focused on the specific results of ob‐ servation and assumed that Stick-Slip phenomenon have a great influence on behavior of paddles. To simulate the influence, we revised the structural model and conducted the ther‐

Stick-Slip phenomenon

Solver MSC.Marc 2011

BC Tip of york : Fixed

**Table 3.** Details of thermal snap analysis

Time step 0.1[sec]

**8. Conclusions**

Thermal-Structure Time transient

352 Advances in Vibration Engineering and Structural Dynamics

Analysis time 360[sec] (After 770[sec] of static state analysis)

cially when the object was weakly illuminated by the Sun.

Analysis type

Mitsushige Oda1 , Akihiko Honda2 , Satoshi Suzuki3 and Yusuke Hagiwara4

1 JAXA and Tokyo Institute of Technologies, Japan

2 Tokyo Institute of technology, Japan

3 Advanced Engineering Services Co.Lted, Japan

44 Mitsubishi Heavy Industries, Ltd, Japan
