Novel Compact LTCC UWB Bandpass Filter with Additional Transmission Zeros on Stop Band

“…When biased appropriately, LDMOS transistor can operates as a switch, which would meet the requirement of class-E PA. But the large output capacitance of LDMOS transistor limits its use for higher switching frequencies [10]. Many design examples of class-E PA using LDMOS transistor are reported in [11][12][13][14].…”

“…The reason why parallel LC circuits (i.e., C 12 in parallel with L C1 -C 11 -L C2 , and C 22 in parallel with L C3 -C 21 -L C4 ) are used for implementing C 1 and C 2 is for improving the roll-off characteristic at high frequency and the depth of the upper notch [10]. Note that the equivalent resistances (R eff ) corresponding to all MSL inductors and MIM (metal-insulator-metal) capacitors are all neglected temporarily to facilitate discussion and will be considered later (in the simulation).…”

Miniature 1.87‐dB insertion‐loss V‐band CMOS bandpass filter with two enhanced finite transmission zeros

“…When biased appropriately, LDMOS transistor can operates as a switch, which would meet the requirement of class-E PA. But the large output capacitance of LDMOS transistor limits its use for higher switching frequencies [10]. Many design examples of class-E PA using LDMOS transistor are reported in [11][12][13][14].…”

“…The reason why parallel LC circuits (i.e., C 12 in parallel with L C1 -C 11 -L C2 , and C 22 in parallel with L C3 -C 21 -L C4 ) are used for implementing C 1 and C 2 is for improving the roll-off characteristic at high frequency and the depth of the upper notch [10]. Note that the equivalent resistances (R eff ) corresponding to all MSL inductors and MIM (metal-insulator-metal) capacitors are all neglected temporarily to facilitate discussion and will be considered later (in the simulation).…”

Miniature 1.87‐dB insertion‐loss V‐band CMOS bandpass filter with two enhanced finite transmission zeros