采用交错贪婪和局部优化方法的小角度辐条脉冲设计。
Small-tip-angle spokes pulse design using interleaved greedy and local optimization methods.
机构信息
GE Global Research, Munich, Germany.
出版信息
Magn Reson Med. 2012 Nov;68(5):1553-62. doi: 10.1002/mrm.24165. Epub 2012 Mar 5.
Abstract
Current spokes pulse design methods can be grouped into methods based either on sparse approximation or on iterative local (gradient descent-based) optimization of the transverse-plane spatial frequency locations visited by the spokes. These two classes of methods have complementary strengths and weaknesses: sparse approximation-based methods perform an efficient search over a large swath of candidate spatial frequency locations but most are incompatible with off-resonance compensation, multifrequency designs, and target phase relaxation, while local methods can accommodate off-resonance and target phase relaxation but are sensitive to initialization and suboptimal local cost function minima. This article introduces a method that interleaves local iterations, which optimize the radiofrequency pulses, target phase patterns, and spatial frequency locations, with a greedy method to choose new locations. Simulations and experiments at 3 and 7 T show that the method consistently produces single- and multifrequency spokes pulses with lower flip angle inhomogeneity compared to current methods.
摘要
目前的激发脉冲设计方法可以分为基于稀疏逼近或基于迭代局部(基于梯度下降的)优化激发脉冲在横向平面上所经过的空间频率位置的方法。这两类方法各有优缺点:基于稀疏逼近的方法可以在一个较大的候选空间频率位置范围内进行高效搜索,但大多数方法都不兼容离频补偿、多频设计和目标相位弛豫;而局部方法可以适应离频补偿和目标相位弛豫,但对初始化和次优局部代价函数最小值敏感。本文介绍了一种方法,该方法将局部迭代(优化射频脉冲、目标相位图案和空间频率位置)与贪婪方法(选择新位置)交错进行。在 3 和 7 T 的模拟和实验中,该方法始终产生比当前方法具有更低翻转角不均匀性的单频和多频激发脉冲。
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