A waveguide bandpass filter made of high-permittivity ceramics

Figure 4 Experiment at RF band; carrier at 462.5625 MHz, sine Ž . Ž. wave of 4 kHz information @voltage amplitude of 0.1 V. a Spec-Ž . Ž . Ž . Ž . trum of transmitted RF signal. b Scope view of h y versus h x . c Ž . Ž . Original information top and recovered information bottom gation. The lagged sy

## Abstract A miniature monoblock bandpass filter with combline‐type, quarter‐wavelength, and capacitive coupling is investigated. The coupling analysis and equivalent circuit consist of the transmission lines, and lumped elements are presented to predict the filter performance. A filter design tec

The advantage of using high permittivity ceramic substrates is to miniaturize the sizes of microstrip bandpass filters. The selectivity and stopband rejection of the designed filters can be improved significantly by utilizing open stubs. The designed filter with appropriate open stub can create tuna

## Abstract Using high permittivity ceramic substrates and capacitive coupling to miniaturize the sizes of Butterworth bandpass filters are investigated. The selectivity and stopband rejection of the designed filters can be improved significantly by utilizing a skew‐symmetric (zero degree) feed str