Active phased array radar is a new type of solid-state radar, which has the characteristics of multi-function, multi-target and high reliability. In active phased array radar, each antenna unit is equipped with a transmitting/receiving module (TR module). The TR module operates in pulse load mode, which requires a constant voltage and pulse current. The TR module of phased array radar is characterized by a high pulse current slew rate and a high pulse repetition frequency of more than 20kHz. It puts forward high requirements on the load dynamic performance of pulse power supply.
In order to meet the increasing pulse repetition frequency and pulse current slew rate of TR module, this paper proposes a switching-linear hybrid method for the application of high frequency pulse load. The switching-linear parallel system is built based on the theoretical analysis. A 1MHz interleaving parallel synchronous rectifier Buck converter based on GaN device and a bidirectional high-speed linear circuit are used in parallel. The method combines high dynamic response speed of linear circuit and high conversion efficiency of switching circuit. The power supply performance of high di/dt pulse load is effectively improved without sacrificing the system efficiency and power density.
The switching-linear hybrid structure and parallel control strategy of pulse power supply are proposed. In order to achieve the high load dynamic response speed, the output impedance characteristics of the linear circuit in each spectrum are explained based on the method of device-level modeling. The operational amplifier compensator of the linear circuit is designed specifically and the bandwidth is configured at 5MHz. It effectively improves the loop bandwidth of the linear voltage regulator circuit so that it could perform fast power tracking. With the improvement of dynamic performance, the quality of the pulse waveform is improved by the correction of the upper and lower edges of the pulse current. In order to achieve high system efficiency, a wide band gap device: GaN EPC2031 is used to increase the switching frequency to 1MHz. By increasing the switching frequency, the filter inductance is reduced to 680nH so that it can efficiently provide the main pulse power at a fast speed. Based on the dynamic loop modeling method of the parallel system, the power ratio of the switching circuit in the whole power system is improved. The linear circuit only operates in the transient load mutation moment and the switching circuit provides main power during the pulse holding period. In this way, the efficiency of the entire power system is effectively optimized.
Aiming at the high frequency radar pulse load with a repetition frequency of 50kHz, mutation current of 15A and a peak power of 120W, this paper establishes a principle prototype of the pulse power supply with the pulse current rise and fall time within 50ns. The output voltage drop is less than 5%. Compared with the mentioned interleaving parallel Buck converter, the dynamic response speed is increased by 5 times and the voltage drop is reduced by 57% under switching-linear hybrid structure. This scheme avoids filling large capacitors on the output side and uses only a 60μF patch capacitor as the energy storage capacitor.
The experimental results show that the pulse power supply based on this architecture can effectively track the ultra-fast load mutation. The volume and cost of the passive components in the pulse load converter are reduced, thus increasing the power density. It can significantly improve the dynamic response capability of pulse power supply and increase the power supply stability of pulse load.
樊靖轩, 施佳楠, 徐子梁, 任小永, 陈乾宏. 基于GaN的开关线性复合高速随动脉冲负载直流变换器[J]. 电工技术学报, 0, (): 139-139.
Fan Jingxuan, Shi Jianan, Xu Ziliang, Ren Xiaoyong, Chen Qianhong. High Speed Switching-Linear Hybrid Followed-up Pulse Load DC Converter Based on GaN Device. Transactions of China Electrotechnical Society, 0, (): 139-139.
[1] Merrill I Skolnik. Radar Handbook(Third Edition)雷达手册. 第三版[M]. 北京: 电子工业出版社, 2010.
[2] 张光义. 相控阵雷达原理[M]. 北京: 国防工业出版社, 2009.
[3] Sun Yong, Jia Lipeng, Hua Ming, et al.Energy storage capacitor optimization of power fluctuation suppression system with pulse load[C]//2021 IEEE Sustainable Power and Energy Conference, Nanjing, 2021: 3096-3101.
[4] 林庄, 倪扬, 杨新国. 紧凑相控阵用大功率脉冲电源设计[J]. 电子技术与软件工程, 2020, 173(3): 229-232.
Lin Zhuang, Ni Yang, Yang Xinguo.Design of high power pulse power supply for compact phased array[J]. Electronic Technology & Software Engineering, 2020, 173(3): 229-232.
[5] 任小永, 白雷, 惠琦, 等. 一种快速动态响应低电压纹波功率因数校正变换器的控制策略[J]. 电工技术学报, 2019, 34(14): 2936-2945.
Ren Xiaoyong, Bai Lei, Hui Qi, et al.Control strategy of power factor correction converter for fast dynamic response and low output voltage ripple[J]. Transactions of China Electrotechnical Society, 2019, 34(14): 2936-2945.
[6] Xu Ye, Ruan Xinbo, Huang Xinze, et al.A two-stage pulsed power supply with ultra-fast dynamic response and low input current ripple for low-frequency pulsed loads[C]//2021 IEEE Energy Conversion Congress and Exposition, Vancouver, 2021: 3068-3072.
[7] 郭强, 李山, 谢诗云, 等. 多相交错并联DC-DC变换器单电流传感器控制策略[J]. 电工技术学报, 2022, 37(4): 964-975.
Guo Qiang, Li Shan, Xie Shiyun, et al.Single sensor sampling current control strategy of multiphase interleaved DC-DC converters[J]. Transactions of China Electrotechnical Society, 2022, 37(4): 964-975.
[8] 范恩泽, 李耀华, 葛琼璇, 等. 基于优化移相的双有源串联谐振变换器前馈控制策略[J].电工技术学报, 2022, 37(20): 5324-5333.
Fan Enze, Li Yaohua, Ge Qiongxuan, et al.Feedforward control strategy of dual active bridge series resonant converter based on optimized phase shift[J]. Transactions of China Electrotechnical Society, 2022, 37(20): 5324-5333.
[9] 高峡, 冯全源. 一种适用于基于纹波的恒定导通时间架构Buck变换器片内纹波补偿方案[J]. 电工技术学报, 2018, 33(4): 892-899.
Gao Xia, Feng Quanyuan.An on-chip ripple compensation scheme for ripple-based constant on-time architecture Buck converter[J]. Transactions of China Electrotechnical Society, 2018, 33(4): 892-899.
[10] Liu Pei-Hsin, Yan Yingyi, Paolo Mattavelli, et al.Digital constant on-time v2 control with hybrid capacitor current ramp compensation[J]. IEEE Transactions on Power Electronics, 2018, 33(10): 8818-8826.
[11] Song Wensheng, Zhong Ming, Luo Shucong, et al.Model predictive power control for bidirectional series-resonant isolated DC-DC converters with fast dynamic response in locomotive traction System[J]. IEEE Transactions on Transportation Electrification, 2020, 6(3): 1326-1337.
[12] 任小永, 王亚坤, 陈宇, 等. 基于虚拟阻抗的LLC谐振变换器并联均流控制[J]. 电工技术学报, 2019, 34(21): 4540-4550.
Ren Xiaoyong, Wang Yakun, Chen Yu, et al.Parallel current sharing control of LLC resonant converter based on virtual impedance[J]. Transactions of China Electrotechnical Society, 2019, 34(21): 4540-4550.
[13] Zhang Yue, Ding Li, Hou Nie, et al.A direct actual-power control scheme for current-fed dual-active-bridge DC-DC converter based on virtual impedance estimation[J]. IEEE Transactions on Power Electronics, 2022, 37(8): 8963-8975.
[14] 赵朝阳, 卢伟国, 胡志凌, 等. 耦合电感序列切换的快速卸载瞬态响应Buck变换器[J]. 电工技术学报, 2020, 35(增刊1): 28-36.
Zhao Chaoyang, Lu Weiguo, Hu Zhiling, et al.Fast unloading transient response buck converter using coupled inductor based on sequence switching control[J]. Transactions of China Electrotechnical Society, 2020, 35(S1): 28-36.
[15] Huang Xinze, Ruan Xinbo, Du Fangjun, et al.A pulsed power supply adopting active capacitor converter for low-voltage and low-frequency pulsed loads[J]. IEEE Transactions on Power Electronics, 2018, 33(11): 9219-9230.
[16] Yu Yao, Harish S. Krishnamoorthy, Srikanth Yerra.Linear assisted DC/DC converter for pulsed mode power applications[C]//2020 IEEE International Conference on Power Electronics, Smart Grid and Renewable Energy, Cochin, 2020: 1-5.
[17] 杨帆, 李林, 朱建鑫, 等.面向高峰均比低频脉冲功率负载的脉冲电流补偿器及其控制方法[J]. 电工技术学报, 2022, 37(16): 4193-4201.
Yang Fan, Li lin, Zhu Jianxin, et al. A pulsed current compensator and control strategy for high peak-to-average-ratio low frequency pulsed load[J]. Transactions of China Electrotechnical Society, 2022, 37(16): 4193-4201.
[18] Hwang Yuh-Shyan, Chen Jiann-Jong, Ku Yi-Tsen, et al.An improved optimum-damping current mode buck converter with fast-transient response and small-transient voltage using new current sensing circuits[J]. IEEE Transactions on Industrial Electronics, 2021, 68(10): 9505-9514.
[19] Kim Dongwook, Baek Jongun, Lee Jisu, et al.Implementation of soft-switching auxiliary current control for faster load transient response[J]. IEEE Access, 2021, 9: 7092-7106.
[20] Yuan Zhibao, Xu Haiping.Pulse power supply with faster response and low ripple current using inductive storage and interleaving technology[J]. CPSS Transactions on Power Electronics and Applications, 2020, 5(1): 54-62.
[21] Ming Xin, Kuang Jianjun, Liang Hua, et al.A fast-transient low-dropout regulator with current-efficient super transconductance cell and dynamic reference control[J]. IEEE Transactions on Circuits and Systems I: Regular Papers, 2021, 68(6): 2354-2367.
[22] Chirag Desai, Debashis Mandal, Bertan Bakkaloglu, et al.A 1.66mV FOM output cap-less LDO with current-reused dynamic biasing and 20ns settling time[J]. IEEE Solid-State Circuits Letters, 2018, 1(2): 50-53.
[23] Liu Xiaosen, Harish K. Krishnamurthy, Taesik Na, et al.A universal modular hybrid LDO with fast load transient response and programmable PSRR in 14nm CMOS featuring dynamic clamp strength tuning[J]. IEEE Journal of Solid-State Circuits, 2021, 56(8): 2402-2415.
[24] Li Kan, Yang Chuanshi, Guo Ting, et al.A multi-Loop slew-rate-enhanced NMOS LDO handling 1-a-load-current step with fast transient for 5G applications[J]. IEEE Journal of Solid-State Circuits, 2020, 55(11): 3076-3086.
[25] Jin Qian, Ruan Xinbo, Ren Xiaoyong, et al.High-efficiency switch-linear-hybrid envelope tracking power supply with step-wave approach[J]. IEEE Transactions on Industrial Electronics. 2015, 62(9): 5411-5421.
[26] Tony Chan Carusone, David A. Johns, Kenneth W.Martin, Analog Integrated Circuit Design[M]. New York: Wiley, 1997.