排序方式: 共有23条查询结果,搜索用时 15 毫秒
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双色激光引信在克服云烟干扰方面具有重要价值。为了减小引信体积,保障导弹内部空间的充裕性,设计了一种基于BCD工艺的双色激光引信专用集成电路芯片。首先,对现有双色激光引信的结构和工作原理做出了详细介绍,引出了单芯片设计的思路和方法,并给出了该芯片集成的子电路的设计方法和仿真结果。该芯片使用0.25 m的BCD工艺制造。经测试使用该芯片驱动双色激光器,芯片供电电压5 V,激光器支路供电电压27 V时,红外激光器输出峰值功率可达30 W,紫光激光器输出峰值功率达25 W,脉宽50~500 ns可调,重复频率1~100 kHz可调,窗口时间1~10 s可调,红外和紫光回波信号在接收部分实现了分离,在功能上成功取代了原系统的4块芯片,实现了系统的简化。 相似文献
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This paper presents an ultra-low-power area-efficient non-volatile memory(NVM) in a 0.18μm singlepoly standard CMOS process for passive radio frequency identification(RFID) tags.In the memory cell,a novel low-power operation method is proposed to realize bi-directional Fowler-Nordheim tunneling during write operation. Furthermore,the cell is designed with PMOS transistors and coupling capacitors to minimize its area.In order to improve its reliability,the cell consists of double floating gates to store the data,and the 1 kbit NVM was implemented in a 0.18μm single-poly standard CMOS process.The area of the memory cell and 1 kbit memory array is 96μm~2 and 0.12 mm~2,respectively.The measured results indicate that the program/erase voltage ranges from 5 to 6 V.The power consumption of the read/write operation is 0.19μW/0.69μW at a read/write rate of (268 kb/s)/(3.0 kb/s). 相似文献
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为了提高无源超高频(UHF)射频识别(RFID)标签的灵敏度和增大工作距离,设计了一种高灵敏度的ASK解调器。在该解调器的包络检波电路中,采用了开启电压补偿技术,以减小电荷传输管的导通压降;并设计了一种无二极管无电阻的参考电平产生电路。基于0.18μm标准CMOS工艺实现了该解调器,其芯片面积为0.010 mm2,满足第2代第1类UHF RFID通讯协议(EPC C1G2)的要求。测试结果表明,当载波频率为900 MHz、调制深度为80%~100%、数据率为26.7~128 kbit/s时,解调器能够解调信号的能量强度范围为-16~+20 dBm。在工作电压为0.8 V时,其功耗仅为0.56μW。 相似文献
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The paper mainly deals with theoretical investigations of the effect of the thickness change of the waveguide layers on the threshold current. It is analyzed according to the result of a numerical simulation that asks how does the shift of the active region position affect the threshold current for a single quantum well (SQW) and double quantum well (DQW) laser diode (LD) with a relatively narrow waveguide. It is found that the variation trend of threshold current and optimum position of QW are different in SQW and DQW LD with 0.2 μm-thick waveguide, which may be due to the higher variation rate of optical loss in DQW LD with the shift of the active region. It is also found that in terms of either SQW or DQW LD, the variation tendency of the threshold current with a different loss coefficient of the p-cladding layer makes little difference for the relatively narrow waveguide LD. Moreover, the variation trend of the threshold current and the optimum position of QW is almost the same in SQW and DQW LD with 0.8 μm-thick waveguide, because the optical loss is small enough and the threshold current is dominated by the optical confinement factor (OCF) in QW. 相似文献
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本文设计了用于机载激光引信的激光脉冲测距发射单元,该发射单元由激光器和驱动电路构成.激光器选择纳秒级脉冲大功率固体激光器,采用半导体激光二极管作为泵浦源,提出了一种获取同步信号的方法,并对其整体结构进行了考虑.为满足引信特殊需要,为半导体泵浦固体激光器设计了专用驱动电路,解决了固体激光器在不同温度下重复频率不稳定性问题,避免了使用体积庞大的致冷器.激光发射单元工作可靠,在很大温度范围内重复频率稳定并灵活可调.5 V电源时,输出峰值功率达2 018 W、脉宽3.3 ns、重复频率达10 kHz. 相似文献
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