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Royo Roig, I.; Fernández-García, R.; Gil, I. Microwave Resonators for Wearable Sensors Design. Encyclopedia. Available online: https://encyclopedia.pub/entry/52048 (accessed on 22 December 2024).
Royo Roig I, Fernández-García R, Gil I. Microwave Resonators for Wearable Sensors Design. Encyclopedia. Available at: https://encyclopedia.pub/entry/52048. Accessed December 22, 2024.
Royo Roig, Iris, Raúl Fernández-García, Ignacio Gil. "Microwave Resonators for Wearable Sensors Design" Encyclopedia, https://encyclopedia.pub/entry/52048 (accessed December 22, 2024).
Royo Roig, I., Fernández-García, R., & Gil, I. (2023, November 24). Microwave Resonators for Wearable Sensors Design. In Encyclopedia. https://encyclopedia.pub/entry/52048
Royo Roig, Iris, et al. "Microwave Resonators for Wearable Sensors Design." Encyclopedia. Web. 24 November, 2023.
Microwave Resonators for Wearable Sensors Design
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The field of flexible electronics is undergoing an exponential evolution due to the demand of the industry for wearable devices, wireless communication devices and networks, healthcare sensing devices and the technology around the Internet of Things (IoT) framework. E-textiles are attracting attention within the healthcare areas, amongst others, for providing the possibility of developing continuous patient monitoring solutions and customized devices to accommodate each patient’s specific needs. 

textile materials flexible resonator textile resonator wearable device washing analysis bending analysis embroidered resonator

1. Principle of Operation and Classification of Microwave Resonators

1.1. Principle of Operation of Microwave Resonators

By definition, a microwave resonator is a structure based on a series of parallel RLC lumped or quasilumped-element equivalent circuits aimed at confining the electromagnetic energy. Microwave resonators are of interest due to the range of applications they offer, principally filters, oscillators, frequency meters and tuned amplifiers [1].
Ideally, a microwave resonator might be prototyped by a simple LC circuit configuration given a frequency close to the resonance [2], neglecting the losses.
According to the transmission line theory, in a case where the resonant circuit sizes are multiples of λ at the fundamental frequency (e.g., half-wavelength resonator, λ/2, or quarter-wavelength resonator, λ/4), the result is no longer acknowledged as a lumped element but rather a distributed line resonator.

1.1.1. Resonance Frequency and Quality Factor: A Brief Description

Resonance Frequency, ω0
In an RLC resonant circuit, the resonance occurs when the magnetic and electric impedances condition is met (XL = XC). The resonance frequency, ω0, is expressed as shown in Equation (1):

Quality Factor, Q
The Q-factor measures the loss of the resonant circuit as the ratio of the resonance frequency to the bandwidth of the circuit, meaning that the higher the Q value, the lower the losses.
The losses in a resonator might have different origins. The Q isolated from any external circuitry effect (without the MUT—Material Under Test—being loaded) is designated as unloaded Q0. This is the higher Q value for the system.
Equation (2) describes the relation between the loaded Q, the resonance frequency f0 and the ±3 dB (half-power) bandwidth of the frequency, Δf. The same is illustrated in Figure 1.

Figure 1. Graph of a bandpass filter Q-factor.
The unloaded Q0 has a logaritmic relation with the inserion loss IL (obtained from S21, measured in dB) as per Equation (3):
 
Therefore, the loaded Q bandwidth, BW, for a circuit with bandpass properties, is given in Equation (4):

The insertion loss increases for a loaded Q near to an unloaded Q0, and a higher loaded Q leads to a narrower bandwidth, which can be very lossy. Hence, in order to avoid excessive losses, unloaded Q0 >> loaded Q.
Since the Q-factor is decisive for the selection of a resonator design (for instance, for filtering applications), multiple configurations have been presented throughout the years in the literature. The length of the lossy transmission line and its termination are the two variables to adjust in order to achieve the desired results. 

1.1.2. Frequency Variation as a Sensing Principle

The resonators of interest in this article sense the variation of the resonance frequency caused when placing the MUT in the sensing area. These are extensively used for the dielectric characterization of solids, liquids and even gases by studying the relation between the f0 and the loaded Q with the material’s dielectric constant or permittivity, εr.
The resonator consists of a sensing area (where the MUT will be placed) and a transmission line. First, an initial value of the resonance frequency without the MUT f0 is obtained, and then the transmission line is loaded with the MUT, which causes a variation of the resonance frequency, f0’. The dielectric properties values are hence obtained by the frequency response shifting of the S21 parameter.
Figure 2 illustrates the frequency variation before and after placing the FUT.
Figure 2. Frequency shift from (a) without MUT to (b) with MUT in the sensing area.

1.2. Classification and Configurations of Resonators

1.2.1. Types of Resonators

Resonators are classified into three main categories: transmission line resonators, waveguide cavity resonators and dielectric resonators. The interest of the present article is the transmission line resonator, specifically the microstrip resonator, which encompasses one or multiple oscillating electromagnetic fields. The transmission line resonant method is a better choice compared to others such as coaxial or waveguide cavity in terms of compactness in size, robustness, elevated sensitivity, and especially because it is easy to fabricate and does not imply the destruction of the MUT. All these benefits make this method the most viable for the design of wearable devices.
These can be classified as below.
Lumped-element resonator and quasilumped-element resonator, which resonate accordingly to the aforementioned Equation (1).
Distributed line resonators, which resonate at a frequency, f, that is a function of the fundamental resonance frequency, f0.
  • Quarter-wavelength (λ/4) resonator (f ≈ (2n − 1) f0 for n = 2, 3, …) with shunt series or shunt parallel resonance.
  • Half-wavelength (λ/2) resonator (fnf0 for n = 2, 3, …).
  • Ring resonator, whose resonance frequency is a function of the ring radius, r (2πr = λ, fnf0 for n = 2, 3, …).
  • And others: stepped impedance resonator (SIR), hairpin resonator, etc.
Patch resonators, which can be shaped into numerous geometries such as circular or triangular.
Figure 3 illustrates the above-mentioned resonators.
Figure 3. Some microstrip resonator structures: (a) half-wavelength (λ/2) resonator; (b) quarter-wavelength (λ/4) open-end stub resonator; (c) ring resonator; (d) circular patch resonator; (e) stepped impedance resonator; (f) hairpin resonator.
Distributed line resonators can be configured in several ways depending on the filtering requirements. In ring resonators, the symmetrical geometry permits the resonance to befall in any orthogonal coordinate, which is a feature of real interest for the design of dual-mode filters [2]. Alternatively, other dual-mode resonating structures have been designed and implemented in both wired and wireless communication methods, such as squared and mender-loop resonators, where this last one is advantageous due to the compact dimensions [3].
For sensing purposes, the typical topologies of resonators that are widely employed are listed below:
  • Electric-LC (ELC);
  • Ring resonators:
    Split-ring resonator (SRR);
    Complementary split-ring resonator (CSRR);
    Open split-ring resonator (OSRR);
    Open complementary split-ring resonator (OCSRR);
    Spiral resonator (SR);
    Complementary spiral resonator (CSR).
Figure 4 illustrates these topologies and their equivalent circuits.
Figure 4. Topologies of the (a) ELC; (b) single SRR; (c) double SRR; (d) double CSRR; (e) OSRR; (f) OCSRR; (g) SR; (h) CSR; and their equivalent circuit models. The ohmic losses would be considered by adding a series resistance in the model. Models reproduced from references [4][5].

2. Materials and Methods in Flexible Electronics

Flexible electronics are considered those electronic devices with the capability to alter their planar structure by bending, folding, twisting, stretching and deforming without altering their electrical properties.
The first investigation toward flexible electronics dates back to the 1960s, when a flexible solar cell arrays prototype made of crystal silicon wafer cells assembled on a plastic substrate was presented [6].
From then onwards, a huge evolution can be observed in terms of design and materials selection in order to achieve the desirable performance, dimensions and adaptability of the electronic devices to match and supersede the huge market demand.
The materials must prove, at least, exceptional mechanical properties and energy generation and storage. Other promising properties might be water resistance, high adhesion, biodegradability and so forth. The author of [7] enumerates the six requirements of flexible substrates:
  • Optical properties: low birefringence and clear substrates are a must for displays.
  • Surface roughness: asperities impact on the electrical function.
  • Thermal and thermomechanical properties: the substrate’s working temperature must support the maximum fabrication process temperature.
  • Chemical properties: avoid contaminants release.
  • Mechanical properties: an elevate elastic modulus is necessary to grant the substrate’s bending and stretching.
  • Electrical and magnetic properties: substrate must either conduct or insulate as per the designs’ requirements.
Multiple layers have to be considered when creating flexible electronic devices: the substrate, the connectors/electrodes and the conductive/functional layers. In [8], a classification of intrinsically soft materials for flexible electronics is given. All details are reported in Table 2.
Table 2. Intrinsically soft materials for flexible electronics [8].
Layer Applications Materials
Substrate Materials Polymers PVA, PET, PI, PU, PE
Flexible and stretchable PEN, PDMS
Eco-friendly and biodegradable Paper, chitin, silk, gelatin
Electrode Materials Soft metals Galinstan alloy, metal nanoparticles and nanowires
Conductive nanomaterials Carbon materials: graphene, carbon nanotube
Conductive polymers PEDOT: PSS, PANI
Hybris materials Carbon/metal, polymer/metal
Functional Materials Cluster materials Molecules, polymers, biomass
Low-dimensional and nanomaterials Nanoparticles and Quantum dots
Nanowires, nanotubes and nanoribbons
Graphene, transmission metal dichalcogenides and mXenes
Organic–inorganic hybrid materials Nanomaterials/polymers

2.1. Conventional Substrates

Traditionally, three different types of materials are used as substrates for flexible applications: metals, organic polymers and thin glass. Their properties are compared in Table 3.
Table 3. Properties of substrates: metal foil, plastic film and thin glass [8][9][10].
Property Metal Foil Plastic Film Thin Glass
Thickness, t Stainless steel 430
100 μm
PEN, PI
100 μm
Glass 1737
100 μm
Flexibility At t < 125 μm High At t < 100 μm
Young’s modulus, E Stainless steel 430
200 gPa
PEN, PI
5 gPa
Glass 1737
70 gPa
Optical transmission visible Opaque PEN and PET semitransparent (optical transmittance >85%) Semitransparent
(optical transmittance >90%)
Resistance to process chemicals High
(Stainless steel)
Poor for PC, PES, PAR, PCO Resistance to most of them
Dimensional stability High Lower than glass High
Temperature tability High Lower than glass High
Temperature tolerance ≤1000 °C ≈200 °C ≤600 °C
Thermal conductivity Stainless steel 430
16 W/m°C
PEN, PI
0.1–0.2 W/m°C
Glass 1737
1 W/m°C
Electrical conductivity Conductive Insulation requires insulating layer coating Insulator
(Except ICPs)
Insulator
CTE 1 Low (<20 ppm/°C) (Stainless steel 430, 304) Low (<20 ppm/°C) (PET, PEN, PI) Low
(≈4 × 10−6 ppm/°C)
Surface roughness ≈1 μm ≈10 μm ≤1 μm
Durability High Lower than metal Lower than metal
Permeability against oxygen and water Impermeable Easily permeated by oxygen and water Impermeable
Roll-to-toll processable Yes Likely Not likely
1 Coefficient of thermal expansion.

2.2. E-Textiles

Given the increase in the manufacturing demand for wearable electronics for body area networks (BANs), the industry is working on the usage of textiles so these can be employed for the design of clothes, shoes and other accessories such as wristwatches. Textiles have been of strong interest in health since the 1990s for the constant monitoring of patient vitals and activities such as electrocardiography, electromyography and electroencephalography. Textile-based electrodes and sensors can be employed for sensing strain, pressure, temperature, heat flux, sweat, humidity, and even gas detection [11].
According to ISO-TR-23383-2020 [12], there is a differentiation between the electrically conductive textiles and the smart textiles (e-textiles): electrically conductive textiles are defined as textiles with integrated e-circuits made of conductive fibers, whereas e-textiles are textile-based products with electronics embedded on them.

2.2.1. Key Properties of Textiles in Electronics

The huge range of fabrics and their particular properties offers the flexibility to select the best choice for each specific application and its desired performance. Several are found in the literature investigating the RF applications (mainly the design of antennas and resonators) on fabric substrates. One of the most commonly used materials is felt, but there are others like goch, leather, jeans, cotton, silk, wax or even combinations of those [13].
In order to not compromise the performance of the sensing device, it is crucial to study and select the appropriate textile. Depending on the industry demand and the applications, some intrinsic properties will be more instrumental than others, either enhancing the electrical capacity and/or granting mechanical features and quality.
Relative Permittivity and Loss Tangent
By definition, the relative permittivity, εr (also known as ‘dielectric constant’, k) determines the ability to polarize a material when exposed to an electrical field [14]. In other words, this is an intrinsic material’s parameter that indicates its capacity to store energy when applying a potential across it [14].
The relative permittivity represents the real part of the complex dielectric permittivity, 𝜀r, which is expressed as shown in Equation (5):

where the permittivity of vacuum, 𝜀0, has a value of 8.854 × 10−12 F/m. The loss tangent, tanδ, is the relation between both the imaginary and the real part, which quantifies the material losses. A small loss tangent (tanδ << 1) is found in low-loss dielectric materials, whereas a large loss tangent (tanδ >> 1) is inherited in lossy dielectrics that demonstrate a limited capacity to store energy [11].
The loss tangent is expressed in Equation (6):

Hence, these two parameters are certainly decisive in the selection of a material for RF microwave applications.
Relative Humidity and Regain
Relative humidity, RH, expresses in percentage the ratio of a water–air mixture against the saturation humidity ratio at a specific temperature.
Moisture regain, MR, expresses the moisture absorption, in other words, the capability to absorb water or moisture from the environment, which is also a percentage. Figure 5 exposes the moisture regains of some natural fibers, according to [15]. Others of interest are found in [16][17].
Figure 5. Moisture regains (%) of natural fibers [15][16][17].
Both relative humidity and temperature have a huge impact on the fibers’ physical properties such as dielectric constant, tensile strength, electrical resistance, rigidity or elastic recovery. The effects will be more notorious in natural and hydrophilic fibers than synthetic polymeric fibers, which are hydrophobic.
In [18], a breaking load test is performed on cotton, polyester and silk samples to compare the effect of the relative humidity on the tensile strength of the fabrics. The results prove that silk and cotton are highly conditioned by the moisture in the environment due to their hydrophilic nature, which results in an evident degradation of their fibers in the case of silk, whereas cotton tends to increase the strength the higher the RH is. This is explained by the cellulosic properties of the material, which permit the release of internal strain by swelling, resulting in a uniform distribution of stress.
In the case of polyester, due to its hydrophobic characteristics and crystalline structure, the tensile strength remains almost unaltered along the different relative humidities.
Relative humidity also has an influence on the electrical properties, in a sense that the presence of moisture alters the relative permittivity, εr: the higher the RH is, the more the εr increases (due to the bigger presence of water, which has a relative permittivity value around 78.4 [19]).
In [20], a study over five samples is performed to analyze the influence of the relative humidity in the electrical properties of fabrics for antenna design. A quadratic relation between the RH and the εr is expressed in Equation (7), which explains how the relative permittivity increases more in accordance with the relative humidity on materials that are naturally more absorbent.

It is also observed in the aforesaid article that the frequency is shifted to lower frequencies as the relative permittivity increases, and the frequency peak widens and flattens as a consequence of additional losses.
Surface Resistance, Surface Resistivity and Conductivity
Surface resistance, Rs, defines the capacity that a material has to resist the electricity flow. In other words, it is the relation between the DC voltage and the current that flows between two electrodes, according to Ohm’s law. It is measured in Ohms (Ω).
The surface resistivity, ρs, is the resistance to current leakage along an insulating material’s surface. Its measurement is in Ohm/square (Ω/sq.) [21].
Electrical conductivity or conductance, σ, is defined as the electrical conduction, meaning the material’s ability to transfer current. The SI unit of conductivity is Siemens per meter (S/m) [22].
These three parameters are related in that the conductivity is inversely proportional to the surface resistivity per a given thickness, t, as shown in Equation (8).

For this reason, it is so important when selecting the conductive fabric for sensing device manufacturing to consider also these three parameters that determine the electrical performance.
Thickness
The substrate thickness is another critical parameter to consider in the design of antennas, sensors, and so on. The fabric thickness and the number of layers, along with the relative permittivity, determine the bandwidth, the gain and the efficiency performance of the corresponding planar antenna or resonator.
Textile materials are generally limited to a narrow range of relative permittivity. Therefore, the fabric thickness becomes more decisive when trying to maximize or minimize the bandwidth. This is explained by the relation with quality factor, Q, according to Equation (9).

where the Q-factor results of the reciprocal relation of losses are shown in Equation (10): space wave (Qrad) losses, conduction ohmic (Qc) losses, surface waves (Qs) losses and dielectric (Qd) losses.


Therefore, the relation with the thickness of the substrate has to do with these losses individually: one characteristic of thin substrates is having elevated space wave losses (also known as ‘radiation losses’). This means that the thicker the fabric, the smaller the overall Q-factor (Qt). Consequently, a larger bandwidth is allowed for a thicker substrate [23].
Flexibility, Elasticity and Mechanical Deformations
Textiles are key given their excellent flexibility and elasticity that allows their perfect adjustment in curved surfaces, as they can bend, elongate and compress. However, these properties may also be a disadvantage, as they lead to inaccurate measurements and dimensions when designing resonators and other electrical components. Also, it is found in the literature that modifying the shape of the sample does also imply a change in the resonance frequency of the device.
Not only this but the fact of bending has also a direct impact on the electrical properties, particularly the bandwidth, since the substrate thickness becomes irregular. This is an important parameter to measure when intending to use the device for human body applications. Here, the weave structure plays an important role as it might enhance the tensile strength.

2.2.2. Textile Substrates

Several articles are found in the literature investigating the RF applications (mainly the design of antennas and resonators) on fabric substrates. One of the most commonly used materials is felt, but there are others like goch, leather, jeans, cotton, silk, wax or even a combination of those [13].
Textiles’ dielectric properties are fully dependent on the dielectric behavior of their fibers, which are generally constituted by polymers. This explains why the relative permittivity of fabrics is so low compared to conventional electronics-related materials in the view of the fact that polymers are largely treated as insulators due to their low electrical conductivity [24].
The dielectric properties of some typical fabrics are listed in Table 4.
Table 4. Comparison of different materials characterized using ring resonator and patch antenna methods.
Ref. Fabric εr tanδ Frequency (GHz)
[25][26] Felt 1.22–1.38 0.0160–0.0230 2.45
[25] Cordura® 1.90 0.0098 2.45
[25] Cotton 1 1.60 1 0.0400 1 2.45
[25] 100% Polyester 1.90 0.0045 2.45
[27] Viscose 1.64 0.0160 2.45
[25] Lycra 1.68 0.0080 2.45
[25] Quartzel® Fabric 1.95 0.0004 2.45
[25] Cordura/Lycra® 1.50 0.0093 2.45
[25] Tween 1.69 0.0084 2.45
[25] Panama 2.12 0.0500 2.45
[25][27] Jeans 1.62–1.70 0.0180–0.0250 2.45
[25] Moleskin 1.45 0.0500 2.45
[27] Fleece 1.20 0.0040 2.40
[27] Felt 1.36 0.0160 2.40
[27] Silk 1.20 0.0250 2.40
[27] Leather 2.95 0.1600 2.40
[27] Neoprene rubber 5.20 0.0250 2.40
[27] Cotton 1.54 0.058 2.40
[27] Polystyrene foam 1.02 0.00009 2.40
[27] Velcro 1.34 0.0060 2.40 & 5.00
[27] Denim 1.80 0.0700 2.40 & 5.00
[27] Tween 1.69 0.0084 2.60–3.95
[27] Silk 1.75 0.0120 2.60–3.95
[26] Polyester plain weave 3.20–3.66 0.018–0.0320 1.00
[26] Flax 4.22–6.20 0.0370–0.058 1.00
[26] Jute 2.99–4.95 0.0310–0.0470 1.00
[26] Hemp 4.08–4.77 0.0280–0.0520 1.00
[26] Wool 4.11–5.70 0.0280–0.0520 1.00
[28] 100% Nylon 6.6 2.82–2.78 0.0268–0.0283 9.80
[28] Denim 1.70 0.085 2.22–2.59
1 More detailed table in [26].

2.2.3. Conductive Fibers and Yarns

The factors that determine the performance of fabrics are, principally, the nature of the fibers, the yarn, the structure of the weave, the density of the thread, the air volume and the surface treatment, if any [29]. However, fabrics are susceptible to environmental conditions such as pressure, humidity, and temperature.
Fabrics are naturally insulating materials made of fibers. It is possible, though, to combine them with metallic fibers, filaments or coatings, or even with conductive polymers, so they become what is known as conductive fabrics or electro textiles. The first reference to this concept found in the literature was in 1952 by S.P. Hersh [30].
Dielectric fabrics are characterized for their really small or negligible conductivity. These are used in electronics as the dielectric substrate for the design of wearable and flexible devices, e.g., sensors, antennas or resonators. Here, the dielectric properties of the textile do truly determine their gain and efficiency.
Conductive Fibers
Conductive fibers can have a metallic, carbonic or polymeric nature. Their properties are enumerated in Table 5.
Conductive Yarns
Conductive yarns are manufactured using purely metallic wires or they are simply core-covered by metal (usually stainless steel) having a conductivity range from 5 Ω/m to more than a few kΩ/m [34]. The classification found in the literature [35] is listed below.
  • Metallic filament yarns (metallic or metallized yarns);
  • Conductive hybrid yarns;
    • Conductive composite yarns or metal composite embroidery yarns (MCEYs);
      Core spun yarns;
      Commingled yarns;
      Blended spun yarns;
    • Bi/multi-component spun yarns;
  • Inherently conductive polymer yarns (ICP);
  • Laminated/coated conductive yarns;
  • New conductive material and nanomaterial yarns.
The selection of the conductive yarn depends on the desired application, provided that each material has a specific conductivity level. Table 6 summarizes the possible applications for each yarn category.

2.3. Manufacturing Techniques

2.3.1. Etching

Etching is a chemical process whose basic principle is to engrave the desired pattern into a substrate by causing a corrosive effect between the photoresist masks and the etchants. In other words, the materials are removed from the board with liquid chemicals. This technique began in the 1960s, and it is also known as chemical etching or liquid etching [37]. Etching allows the manufacture of complex patterms with a high level of accuracy compared to other technologies.

2.3.2. Soldering and Welding

Both soldering and welding are joining techniques. These are widely used in flexible textile electronics to connect components and connectors to the conductive textile substrates (threads, flexible copper wires, polymides) [38].
In soldering, a filler metal (or solder) is melted to join two contacts. This third metal must have a lower melting temperature than the conductive thread or fabric. The conventional soldering technique requires high temperatures (above 200 °C), whereas lower temperatures (150 °C) are enough and required when working with fabric. However, not all conductive threads are suitable for soldering, for instance, stainless steel. The solder is a soft alloy of lead (Pb), tin (Sn) or silver (Ag) [39]. Some examples of the soldering technique applied to smart textiles is the integration of LEDs to the textile substrate using soldering conductive yarns [40].
Welding, similar to soldering, requires high temperatures to melt in this case both the metal and the textiles so they can be joined. This technique is seldom employed for e-textiles manufacture given the temperature conditions that limit the appropriate materials to use. The three main categories [41] are outlined below:
  • Resistance welding: This requires two metallic parts to be joined by applying an electrical current through them.
  • Ultrasonic welding: The ultrasonic acoustic vibrations with frequencies between 20 and 40 kHz generate heat and pressure that end up welding the two parts [42]. This is the most popular welding process with applications in multiple areas such as automotive, aerospace and health. An example is [43], where rotating ultrasonic welding technology is employed to integrate highly conductive ribbons into textile-based conductive tracks.
  • Radio-frequency (RF) welding: The RF absorbing polymer tape is positioned in the middle of the two fabric pieces, which melts by submitting to RF energy. This technique is of interest for non-weldable fabric materials.

2.3.3. Adhesive Conductive Foil

Conductive adhesive is commonly used in the shape of a sheet or strip especially for prototyping due to its low cost and easiness of employment. Adhesive copper tapes can be stuck or glued to many surfaces, e.g., ceramic cylinders [44], copper-clad substrates [45] or even textiles [13][46].
Copper foil tapes are commercialized in rolls and sheets of many dimensions and thicknesses. It is a remarkably modest material provided that the manufacturing process can be as elementary as cutting the strips manually with scissors to drawing the layout using a dedicated software and after printing and cutting it with a draft cutter.
The results, though, may not be indicated for purposes others than protoyping and pretesting or academic when it comes to employing this technique onto textiles because of their low reliability due to a lack of adherence over time (which impacts the sensing accuracy) compared to other technologies such as printing or embroidery.

2.3.4. Printing Technologies

A wide range of technologies can be employed for printing electronic components. These are advantageous for their lightness, low profile and low cost compared to the conventional technologies, e.g., etching [47].
The printing processes can be divided in two categories [48]:
  • Conventional printing: These are printing technologies that require a master (printing plate), which is basically the tool that enables the ink transfer to the printing substrate. The conventional printing processes are outlined below:
    • Screen printing;
    • Letterpress/flexography;
    • Lithography/offset;
    • Gravure printing.
  • Non-impact printing: These are masterless printing technologies (also known as ‘non-contact printing’ processes). These technologies employ laser to transmit the information to the intermediate carrier that will afterwards transfer it to the final substrate. The non-impact printing processes are outlined below:
    • Electrophotography;
    • Inkjet printing;
    • Ionography;
    • Magnetography;
    • Thermography;
    • Photography.
The application will determine in the vast majority of cases which is the most suitable printing technique. Generally, the minimum dot (feature) size and the throughput are the two main parameters to check against. However, others may also be taken into consideration [49].
Out of all the list enumerated above, screen-printing and inkjet-printing technologies have become the most relevant processes in the design of sensors and other electronic devices.
Screen Printing
Screen printing consists of the usage of a squeegee to apply pressure to the ink paste over a screen stencil, which is placed on top of the substrate. The stencil acts as a mask, meaning that the ink is imprinted through the non-covered cavities.
This technology is widely employed in electronics due to the good compatibility of materials, the low cost and the easiness of manufacturing [45]. However, the need to use a mask introduced an additional expense and material waste that may not be convenient when rapid prototyping [50][51].
Many applications are found in the literature for the design of RF antennas [52], RFID [53], smart packaging [54], plant biomarkers measurement [55], nitrate detection in water [56], monitoring metal pollutants [57], other smart wearables [58], IoT applications [59] and even electroluminescent matrix displays [60].
Inkjet Printing
Inkjet-printing technology is a contactless alternative widely employed for R&D and some other specific applications which involve the fabrication of latches [48]. It can either work with liquid or hot-melt ink. The functioning consists of the deflection of charged ink droplets by electric fields, which draws the desired image controlled electronically [47].
This technology has many variants—continuous ink jet, thermal (bubble) ink jet, piezo ink jet—that are used in accordance with the drop diameter and frequency.
In the literature, many applications are found for printed electronics, such as printed circuits, transistors, and amplifiers, in the design of antennas, sensors, RFID and audio devices. Many flexible color displays have also been developed so far using this technology [48]. Also, in the field of microwave technology, a recent (2020) study [61] has proven the feasibility of integrating circuits into microfluidic systems for heating and sensing purposes.
Comparing Screen Printing and Inkjet Printing
Screen- and inkjet-printing techniques are the most effective options in the field of printed electronics. While screen printing requires a stencil or master, it is still the best choice for mass production given the price–scalability compromise. On the other hand, inkjet printing is more recommended for prototyping and testing as long as it does not require a master [49].
In terms of the quality of the textile print, an experimental study [62] discloses the pigmentation outcomes of each technique on non-treated and pre-treated cotton fabrics.
The results show that inkjet-printed samples have an ink density three times lower than screen-printing ones, meaning that multiple passes are needed to obtain the same. Despite that, the color saturation is not affected by this factor but rather by the fabric properties, returning higher values for pre-treated cotton samples in general but still lower when using inkjet ink due to their viscosity and surface tension.
Between the four primary ink colors (magenta, cyan, yellow, black), many differences are also found that relate the viscosity with the density on each fabric.

2.3.5. Three-Dimensional (3D) Printing

With a wide range of commercially accessible printing methods and materials, additive 3D printing techniques have recently gained appeal, especially for the development of flexible antennas, mainly because of the wide range of materials that can be employed under the classification of polymers and resins, metals and ceramics.
Additive Manufacturing (AM) by 3D printing is attracting the attention of the scientific collective given the flexibility, cost-effective, simple and fast prototyping alternatives that it brings. The basic principle of this technology is the addition of subsequent layers of materials in the desired digital design until reaching the desired tridimensional figure. In this way, the width of the 3D-printed substrate will depend directly on the material used and on the number of stacked layers. Multiple AM techniques exist; the more common are listed below [63][64]:
  • Fused Filament Fabrication (FFF) or Fused Deposition Modeling (FDM);
  • Stereolithography (SLS);
  • Digital Light Processing (DLP);
  • Material Jetting (MJ).
Fused Deposition Modeling (FDM) is the most popular technique, which encompasses the high-temperature extrusion of the filament modeling the object from bottom to top. In the literature, several studies provide successful results of implementing FFF technology for the design of RFID antennas [65][66][67], broadband 5G on-package antennas [68], SRRs [69][70], microstrip resonators [71], dielectric resonator reflectarrays [72], and others.

2.3.6. Embroidery

Embroidery has become one of the most commonly used manufacturing techniques in the field of smart textiles, as it has been extended to multiple applications in aerospace engineering, construction, automotive, medicine and biomedical, amongst others [73]. This technique comprises the application of conductive yarn materials in a patterned design into a textile substrate.
Standard embroidery (or two-thread system) is the regular system generally employed to apply onto the textile a combined fine metal wire along with the yarns [74]. The Tailored Fiber Placement (TFP, also known as the ‘three-thread system’) dates back to the 1990s [75] and is an automated process that allows total control over the orientation and the directionality of the fibers in a composite preform. Using this technique, it is possible to build tridimensional structures of many shapes. The TFP method is recommended for glass or carbon fiber threads which are rigid and thick [76].

2.3.7. Weaving and Knitting

Weaving and knitting are two textile fabrication methods which allow the fabrication of 2D and 3D fabric structures by working with multiple warp and weft layers. The knitting process comprises the positioning of the yarns on a knitting needle defining consecutive loops or stitches that are connected either horizontally (weft) or vertically (warp) [77]. In the weaving process, the yarns are interlaced perpendicularly, which simplifies the exercise to insert the conductive yarn.
Weaving and knitting are recommended techniques especially when the desire textile surface’s dimensions are huge. The most remarkable properties of woven and knitted fabrics are outlined below:
  • Lightweight;
  • Portability;
  • Skin comfort;
  • Durability;
  • Deformation resistance (woven fabrics);
  • Elasticity and stretchability, air permeability, thermal retention (knitted fabrics).

2.3.8. Comparison of Wearable Electronics Integration Techniques

Table 7 summarizes all the aforementioned techniques. Figure 6 illustrates some application cases of resonator design employing them.
Figure 6. Some examples of wearable electronics manufacturing techniques: (a) Wet Etching: flexible split-ring resonator metamaterial structure fabricated on a polypropylene film by chemical etching [78]; (b) Welding and Soldering: components surface-mounted soldered to conductive fabric. Reproduced with permission. Copyright Liza Stark (http://thesoftcircuiteer.net/); (c1,c2) Adhesive Conductive Foil: implementation of (c1) a ring resonator and (c2) a stub resonator on textiles using adhesive copper tape [13]; (d1,d2) Screen Printing: (d1) an illustration of a conventional screen-printing process; (d2) prototype of 60 GHz flexible meta surface made of a unit cell of circular metallic rings embedded with a square-shaped ring and printed on Melinex [79]; (e) Inkjet Printing: split-ring resonator fabricated using an ink-jet printer using ink with silver nanoparticles [61]; (f) 3D Printing: chipless RFID tag made of rectangular slot ring tags, different IDs (left to right): ‘1111111111110’ and ‘1010101010100’ [80]; (g1,g2) Embroidery: (g1) embroidery methods (from left to right): standard embroidery and TFP [76]; (g2) embroidered transmission line loaded with a split-ring resonator on felt substrate with a satin pattern (60% density) [81]; (h1,h2) Weaving and Knitting: (h1) different knitted plain structure-based sensors and (h2) illustrated simulation of plain knit structure composed of conductive yarn and non-conductive yarn made from 100% polyester [77].
Table 7. Summary of the main advantages and challenges of the most common wearable electronics integration techniques.
Technique Advantages Limitations
Wet Etching Controllable etching rate
Complex designs
High resolution
Chemical contamination
Depends on orientation
Undercutting
Not for small batch production
Influenced by temperature and concentration of etchant
High costs
Soldering and Welding Low contact resistance
Easy manufacture
Efficient mass production
Low cost
Compatible with standard electronics processes
Ultrasonic welding: not contaminant, biocompatible
Mechanically fragile
Requires reinforcing when bending or stretching (not flexible at all)
Requires high temperature
Limited materials
Adhesive Conductive Foil Low cost
In-house made
Flexible
Good for prototyping
Low curing temperatures
Environmentally friendly
Disengages easily
Low accuracy
Not suitable for complex designs
Fragile, easy to break
Poor resolution
High contact resistance
Inkjet Printing No printed form is needed
Ideal for prototyping
High-quality prints
Small losses
Limited colors
Elevated cost of inks
Poor print quality
Slow print
Screen Printing Price competing
Good ink processability
Efficient mass production
Applicable to a final product
Very flexible and stretchable
Ideal for simple design
Printed form is required
Long set up time
Limited layer thickness
Not efficient for prototyping or small batch production
Huge waste of water
Not possible in-house
3D Printing In-house made
Fully digital
Fast fabrication
Flexibility in materials
Complex shapes and structures
Adaptable density
Lightweight
Difficult scalability
High cost of AM manufactured material per weight
Inconsistent quality
Lossy materials
Thermal instability
Bending difficulties
Poor resolution
Embroidery 2D and 3D structures
Freedom of fibers orientation
Good for prototyping
Reduced waste
Stable textile structures
Very flexible and stretchable
Precise and digitized (CAD)
Variety of materials
Scalability, mass production
Low precision in complex designs
Difficult to automate
Requires sealing to avert electrical shorting
Slow process
Performance impacted when bending or washing
Weaving and Knitting Highly automated
Stable textile structures
Robust textile structures
Requires sealing to avert electrical shorting
Fragile, easy to break
Limited choice of yarns
Performance impacted when bending or washing

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