Precise regulation of stem cell self-renewal versus differentiation is important for the maintenance of tissue ho- meostasis. Early loss of stem cell activity results in premature ageing, while excess stem cell activi...Precise regulation of stem cell self-renewal versus differentiation is important for the maintenance of tissue ho- meostasis. Early loss of stem cell activity results in premature ageing, while excess stem cell activity leads to over- proliferation and cancer initiation (Fuchs et al., 2004; Scadden, 2006; Jones and Wagers, 2008; Morrison and Spradling, 2008). Thus, understanding the mechanism con- trolling stem cell self-renewal and differentiation is critical for development of potential clinic therapy in the future.展开更多
The best active twist schedules exploiting various waveform types are sought taking advantage of the global search algorithm for the reduction of hub vibration and/or power required of a rotor in high-speed conditions...The best active twist schedules exploiting various waveform types are sought taking advantage of the global search algorithm for the reduction of hub vibration and/or power required of a rotor in high-speed conditions. The active twist schedules include two non-harmonic inputs formed based on segmented step functions as well as the simple harmonic waveform input. An advanced Particle Swarm assisted Genetic Algorithm(PSGA) is employed for the optimizer. A rotorcraft Computational Structural Dynamics(CSD) code CAMRAD II is used to perform the rotor aeromechanics analysis. A Computation Fluid Dynamics(CFD) code is coupled with CSD for verification and some physical insights. The PSGA optimization results are verified against the parameter sweep study performed using the harmonic actuation. The optimum twist schedules according to the performance and/or vibration reduction strategy are obtained and their optimization gains are compared between the actuation cases. A two-phase non-harmonic actuation schedule demonstrates the best outcome in decreasing the power required while a four-phase non-harmonic schedule results in the best vibration reduction as well as the simultaneous reductions in the power required and vibration. The mechanism of reduction to the performance gains is identified illustrating the section airloads, angle-of-attack distribution, and elastic twist deformation predicted by the present approaches.展开更多
基金supported by the grants from the National Natural Science Foundation of China(Nos.31271582 and 31471384)Temasek Life Sciences Laboratory and Singapore Millennium FoundationBeijing Municipal Commission of Education (No.010135336400)
文摘Precise regulation of stem cell self-renewal versus differentiation is important for the maintenance of tissue ho- meostasis. Early loss of stem cell activity results in premature ageing, while excess stem cell activity leads to over- proliferation and cancer initiation (Fuchs et al., 2004; Scadden, 2006; Jones and Wagers, 2008; Morrison and Spradling, 2008). Thus, understanding the mechanism con- trolling stem cell self-renewal and differentiation is critical for development of potential clinic therapy in the future.
基金supported by Basic Science Research Program through the National Research Foundation of Korea (NRF)funded by the Ministry of Education (No. 2017R1D1A1A09000590)
文摘The best active twist schedules exploiting various waveform types are sought taking advantage of the global search algorithm for the reduction of hub vibration and/or power required of a rotor in high-speed conditions. The active twist schedules include two non-harmonic inputs formed based on segmented step functions as well as the simple harmonic waveform input. An advanced Particle Swarm assisted Genetic Algorithm(PSGA) is employed for the optimizer. A rotorcraft Computational Structural Dynamics(CSD) code CAMRAD II is used to perform the rotor aeromechanics analysis. A Computation Fluid Dynamics(CFD) code is coupled with CSD for verification and some physical insights. The PSGA optimization results are verified against the parameter sweep study performed using the harmonic actuation. The optimum twist schedules according to the performance and/or vibration reduction strategy are obtained and their optimization gains are compared between the actuation cases. A two-phase non-harmonic actuation schedule demonstrates the best outcome in decreasing the power required while a four-phase non-harmonic schedule results in the best vibration reduction as well as the simultaneous reductions in the power required and vibration. The mechanism of reduction to the performance gains is identified illustrating the section airloads, angle-of-attack distribution, and elastic twist deformation predicted by the present approaches.
