Abstract

A microstrip lowpass filter based on transmission line elements for UWB medical applications is proposed in this paper. The filter is constructed of two symmetric shunt open-circuited stubs and three series unit elements. The filter is designed to exhibit an elliptic function response with equal ripple in the passband and the rejection band. A prototype is successfully designed, fabricated, and measured, where a good agreement is attained. The filter shows a high filtering selectivity and an ultra-wide stopband up to 20 GHz with an attenuation level of more than 20-dB. The filter is compact and has a low insertion loss and an ultra-wideband (UWB) rejection which makes it attractive for many technologies such as UWB medical applications.

1. Introduction

Ultra-wideband (UWB) technology has several features which makes it suitable for the application of medical monitoring such as penetrating through obstacles, high precision ranging at the centimeter level, low electromagnetic radiation, and low processing energy consumed. These monitoring applications could be patient motion monitoring, wireless vital signs monitoring of human body, and the medicine storage monitoring. One of the primary passive components of the UWB systems is lowpass filter which is necessary for blocking unwanted signals and suppressing spurious harmonics.

Lowpass planer filters with sharp roll-off, wide stopband, compact circuit size, and low insertion loss are in high demand in modern wireless communication systems and military radar receiver systems for blocking unwanted signals and suppressing spurious harmonics. A general common microstrip structure of lowpass filter is using high and low impedance (stepped-impedance) transmission lines which is known as stepped-impedance lowpass filter [1]. This type of filter has simple design methodology but it exhibits a poor skirt selectivity and a very low attenuation level at the rejection band. In order to improve the filter performance at the stopband, the low-impedance line can be replaced with a quarter guided wavelength open-circuited stub [2]. The open-circuited stub shorts can out the transmission at the resonant frequency and therefore a wider rejection band with a transmission zero can be obtained. Alternatively, a longitudinal slot can be implemented in the ground plane of a stepped-impedance filter to enhance its performance [3]. Due to the slow-wave effect of the slot-back microstrip line, the filter can exhibit a wider stopband and a sharper cut-off compared with the conventional filter. Other techniques can also be used to enhance the performance of the stepped-impedance filters such as stepped-impendence hairpin resonators [4, 5], folded stepped-impedance resonators [6], defected ground-plane structures (DGS) slot [712], and interdigital or semicircle defected ground-plane structures (DGS) [13, 14]. In addition, various methods and structure have been developed to enhance the performance of microstrip lowpass filters such as using circular-shaped patches and open stubs [15], rat-race directional couplers [16], stepped-impedance spiral resonator [17], combination of DGSs and a transformed radial stub (TRS) [18], T-shaped microstrip resonator cells [19], and coupled-line stub-loaded hairpin unit [20] and triangular and radial patch resonators [21].

Lowpass filter can also be designed using distributed elements such as open-circuited stubs and unit elements [2]. This type of filter has spurious harmonics and therefore, it requires more elements to enhance its performance. Alternatively, a cross-coupling can be introduced between the input/output feed lines to allow the filter to exhibit additional transmission zeros at the rejection band [22]. This proposed filter can be used in many technologies such as UWB medical applications [23].

A compact lowpass filter with an elliptic function response and a very wide rejection band is introduced in this paper. The filter is constructed of three series unit elements and two shunt open-circuited stubs. The filter is designed to provide an equal ripple in the passband and the rejection band. It is designed to have a passband with a sharp selectivity and an ultra-wide stopband. The proposed designed is implemented on a microstrip substrate and fabricated using printed-circuited-board (PCB). The filter design, analysis, and measurement results are demonstrated in detail.

2. Filter Design

The 3-dimensional view of the microstrip design of the proposed filter is shown in Figure 1 and Figure 2 illustrates its transmission line equivalent circuit model. The filter is comprised of two symmetric shunt open-circuited stubs, with a characteristic impedance of , separated by three series unit elements or connecting lines with characteristic impedances of and . The open-circuited stub has an electrical length of while the electrical lengths of the unit elements are described by and .

The matrix () of the equivalent circuit model can be written aswhere is the matrix of the open-circuited stub and is the matrix for the unit elements (for ) which can be defined byFor a feed line impedance of , the insertion loss () and return loss () responses can be computed as follows:In general, a transmission line filter with quarter-wavelength elements ( at ) has all of its transmission zeros at a single frequency, e.g., midstopband frequency (). Therefore, it requires more elements to enhance the selectivity and to increase the bandwidth of the rejection band. Alternatively, the circuit elements are designed to have different or unequal electrical lengths to allow the filter to exhibit three transmission zeros inside the rejection band, at ,  , and . In this case, the electrical lengths are chosen to be at the midstopband (). In order to show the performance of this new structure, the filter is designed to have a cut-off frequency at about 3.0 GHz. The filter is also designed to have a return loss of more than 24-dB within the desired passband and an insertion loss of more than 20-dB over the whole rejection band. Furthermore, the filter is designed to generate three transmission zeros at the rejection band at 4.0 GHz, 12 GHz, and 20 GHz. In order to achieve this, the circuit model is optimized based on the above formulations and the calculated parameters are displayed in Table 1. The calculated magnitude response, of the circuit model using the parameters values in Table 1, is demonstrated in Figure 3. As can be noticed, the filter exhibits three transmission zeros which are widely separated from each other providing a very ultra-wide rejection band with high selectivity. These transmission zeros are generated by the two open-circuited stubs. This is because the length of each open-circuited stub () is a quarter-wavelength at 4.0 GHz and therefore, its fundamental resonant frequency is generated at 4.0 GHz and it has spurious resonant frequencies occur at odd multiples of the fundamental one. Hence, the first and second spurious resonant frequencies are located at 12 GHz and 20 GHz as shown in Figure 4. Since the first three resonant frequencies of the open-circuited stubs are located inside the rejection band, the filter exhibits vey wide stopband. The filter exhibits an equal ripple for the return loss at the passband and for the insertion loss at the rejection band. Furthermore, addition, the first resonant frequency of the stub is located close to the cut-off frequency of the lowpass filter leading to a sharp rate of cut-off.

3. Microstrip Design and Experiment Results

The proposed filter design is constructed on a RT Duroid 5880 substrate with and thickness 0.254 mm and the microstrip layout is demonstrated in Figure 5. Based on the microstrip design equations in [2] with a slight tuning, the parameters of the microstrip layout are as follows:  mm,  mm,  mm,  mm,  mm,  mm,  mm,  mm,  mm,  mm,  mm,  mm, and  mm. The open-circuited stubs are folded in a rectangular spiral shape to reduce the filter size. The distance is optimized to have no effect on the filter performance. The microstrip layout is simulated using a commercially available tool [24] and the simulated performance is compared with the calculated results as depicted in Figure 6. Good agreement between the theoretical and simulated responses is obtained. However, there is a slight difference between the simulated and the theoretical passband. The microstrip layout can be further tuned to reduce the effect of discontinuity and to obtain a better agreement. A prototype of this filter is successfully fabricated and measured and Figure 7 shows a photograph of the fabricated filter. The fabricated filter is very small with an overall size of about 18.0 mm by 3.75 mm. The measured performance of the prototype is compared with the simulated results and demonstrated in Figure 8. The experimental filter shows excellent results with an insertion loss of about 0.4 dB at the passband centre frequency. It also exhibits an ultra-wide rejection band up to 20 GHz with three transmission zeros and an attenuation level of more than 20-dB. The filter shows an equal ripple for the return loss at the passband and for the insertion loss at the stopband. A performance comparison between published works and proposed filter is demonstrated in Table 2. It can be noticed that the proposed filter shows wider stopband bandwidth.

4. Conclusion

In this paper, a microstrip lowpass filter based on transmission line elements is proposed. The filter has been constructed of three series unit elements between two symmetric shunt open-circuited stubs. The filter has been designed to have a cut-off frequency at about 3.0 GHz. In order to allow the filter to exhibit an equal ripple in both passband and rejection band, the open-circuited stub has been designed to have its first three resonant frequencies inside the stopband. A prototype has been successfully designed, fabricated, and measured, where excellent agreement between the expected and measured performances is obtained. The filter exhibits a quasielliptic function response leading to a high filtering selectivity and an extended stopband up to 20 GHz with an attenuation level of more than 20-dB. Due to the small size, low insertion loss, and wide rejection band, the proposed filter looks attractive for making it attractive for many technologies such as UWB medical applications.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This work is sponsored by King Abdulaziz City for Science and Technology (KACST).