After sputtering with N-Cr a microstructure of temperature-sensitive sensor was formed and its character of R-T and thermal response time constant were measured .

然后在微桥上溅射镍&铬电阻薄膜，形成温敏传感器微结构，并对其温度电阻特性， 热 响应 时间进行了测量。

Experimental results included the real thermal responses of several tissues under single ruby laser pulse and CW CO-2 laser . The thermal response difference was also discussed with variable duration time temperature rise peak and rise time .

实验记录了单个红宝石激光脉冲、连续CO2激光作用下多种组织的热响应过程，从辐照 时间、温升峰值、上升时间等角度讨论了不同组织、不同条件下组织 热 响应的差异。

At the same time over more temperature and thermal response time would be also varied from the different testing point location .

同时过余温度和 热 响应 时间也将会因为各测点位置的不同而相应产生不同的变化。

It is concluded that the temperature sensor has good linearity and thermal stability within the temperature range and can response very fast . Its response time is only 0.8 ms.

对研制的 薄膜 热电偶温度传感器进行了静态和动态标定，结果表明传感器在0-600℃测温范围内具有很好的线性和 热稳定性，而且 响应快， 时间常数小于0.8ms。

Experiments show that the thermal response stage takes a long time when to simulate more than a dozen cores of microprocessor .

实验表明，当ATMI模拟器在模拟十几个核的处理器 温度的时候， 热 响应阶段的 计算需要一个周的 时间。