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Field of the invention

The present invention relates to a textile fabric implementing a capacitive grid.

In particular, the textile fabric implementing a capacitive grid may be worn on human skin.

Background of the invention

As it is known, textile research refers to any material made by interlacing fibres and traditionally deals with the types of construction as well as the materials and the methods used to create those constructions.

Modern e-textile applications are known in which electric or electronic technology is coupled with the textile technology for a variety of applications, such as sensors for monitoring the health of the wearer, for providing anti- theft functions, for monitoring the physical activity of the wearer, and so on. Most sensors are made of separate parts to be put on garments, are either in a solid state (not stretchable) or a non-breathable condition and implement no moisture management or dye-ability features, which are fundamental features for fashion items or textiles in general.

US 8,823,395 B2 discloses an electronic textile and a method for determining a functional area of an electronic textile.

The electronic textile comprises a textile substrate having a first plurality of conductors, a second plurality of conductors and a plurality of capacitors, each capacitor comprising a conductor from the first plurality of conductors and a conductor from the second plurality of conductors, separated by a dielectric, wherein the capacitors are distributed across substantially an entire surface of the electronic textile.

This electronic textile can be tested to determine if the capacitors between the conductive yarns are a part or not of the functional area of the device. The test procedure consists in sending a voltage to selected conductive yarns in order to detect the capacitance of capacitors comprised between the selected crossing yarns and to evaluate if it is part or not of the functional area, namely in order to determine whether or not the LED under investigation is accessible.

GB 2 443 208 discloses a textile pressure sensor that is flexible, suitable for producing precise and repeatable measurements of locally applied forces. This textile pressure sensor operates by measuring the actual capacitance between two crossing core-spun yarns which have an isolating coating over a conductive core.

US 8,395,317 discloses a textile product having a multi-layer warp which includes an upper warp layer comprising an upper array of conductive warp yarns, a lower warp layer comprising a lower array of conductive warp yarns, and an intermediate warp layer arranged between the upper and lower warp layers.

The textile further includes a weft in which a first set of conductive weft yarns cross the upper array of conductive warp yarns, such that electrical contact is achieved therebetween, and a second set of conductive weft yarns cross the lower array of conductive warp yarns, such that electrical contact is achieved therebetween. Such textile product is suitable for several identical components such as LEDs or sensors, namely for stacking LEDs on fabrics for lighting applications.

In textile applications it is problematic to design a capacitive sensor for the human skin because it is easy for the detection elements, such as conductive electrodes, to parasitically and capacitively couple to the body. Such sensors appear to be useless as an addition of finger/hand capacitance does not make a significant change in the time constant of the detection node.

Summary of the invention

It is an aim of the present invention to overcome the drawbacks of the prior art in order to create a touch-screen-like textile fabric surface wearable on the human skin able to damp the parasitic capacitance of the portion of human skin on which the textile is worn such that a finger touch is detectable. Another objective is to create one-direction and two-direction textile swipe sensors wearable on human skin.

Another objective is, while at the same time creating a sensor fabric, to keep at least the minimum essential features of a garment, such as breathability, moisture management, stretchability, dyeability and also fashion appeal. These and other objects are reached by the present invention by means of a textile fabric comprising:

- a first set of electrically conductive, externally isolated yarns separated by isolating textile yarns;

- a second set of non-isolated conductive yarns;

- a plurality of textile yarns interlacing the first and the second set of yarns, wherein part of the interlacing textile yarns are non-isolated conductive yarns in order to form an electrical grounding grid with the non-isolated conductive yarns of the second set of yarns and part of the interlacing textile yarns are isolating textile yarns.

An effect of the above embodiment is that the electrical grounding grid operates as a barrier to damp the parasitic capacitance of the leg, or other body portion, underneath the capacitive grid such that a finger touch is detectable.

Advantageously, the textile fabric according to the present invention allows an improved detection of a finger touch in a capacitive sensor wearable on human skin.

According to the above embodiment, the first set of electrically conductive, externally isolated yarns, the isolating textile yarns and the second set of non-isolated conductive yarns form a single textile layer. Advantageously, the above embodiment provides a textile layer that is able to implement the function of sensing external touches, isolating and grounding the parasitic capacitance of a body portion beneath it, being at the same time a very thin layer.

Another advantage of the above embodiment is that the textile fabric as above can be used as a multi-direction swipe-sensitive capacitive sensor.

A further embodiment of the invention provides a swipe-sensitive capacitive sensor comprising:

- a textile fabric having a first set of electrically conductive, externally isolated yarns;

- a second set of non-isolated conductive yarns; and

a plurality of textile yarns interlacing the first and the second set of yarns, wherein part of the interlacing textile yarns are non-isolated conductive yarns in order to form an electrical grounding grid with the non-isolated conductive yarns of the second set of yarns and part of the interlacing textile yarns are isolating textile yarns,

wherein the yarns of the first set are arranged in a substantially parallel fashion along a direction and are connected to an input stage configured to measure a variation of the capacitance of the yarns of the first set due to the interaction with an external object which parasitically couples its capacitance to the capacitance of the yarns.

Advantageously, the above embodiment provides a double layer textile that can be used as a double direction swipe-sensitive capacitive sensor. In other words, the above embodiment provides a capacitive sensor that can detect a swipe touch along any direction in the plane of the fabric.

Still another embodiment of the invention provides a swipe-sensitive capacitive sensor comprising

- a textile fabric having a first set of electrically conductive, externally isolated yarns,

- a second set of non-isolated conductive yarns forming an electrical grounding grid,

- a plurality of textile yarns interlacing the first and the second set of yarns, wherein part of the interlacing textile yarns are non-isolated conductive yarns in order to form an electrical grounding grid with the non-isolated conductive yarns of the second set of yarns and part of the interlacing textile yarns are isolating textile yarns,

wherein the yarns of the first set are arranged in a substantially parallel fashion along a first direction and a second direction and are connected to an input stage configured to measure a variation of the capacitance of each of the yarns of the first set due to the interaction with an external object which parasitically couples its capacitance to the capacitance of the yarns.

Advantageously, the above embodiment provides a multiple direction swipe- sensitive capacitive sensor.

Another advantage of the above embodiment is an improved grounding function of the textile fabric since the bottom portion of the textile fabric, i.e. the portion of the textile fabric in contact with the body portion covered by the fabric, presents only non-isolated and isolating textile yarns.

Another object of the present invention is an article, preferably a garment, according to claim 15 and 16. The article is characterized by comprising a textile fabric as above discussed.

A further object of the present invention is a method according to claim 17 for producing a textile fabric acting as a swipe sensor and an article as above discussed. The method includes the steps of producing a woven textile fabric comprising at least a set of electrically conductive and externally isolated yarns extending along at least a first region of the fabric, said first region having a first weaving structure according to claim 1 , wherein said electrically conductive, externally isolated yarns extend also along at least a second region, said second region having a second weaving structure different from said first weaving structure; cutting the thus obtained fabric along at least a cut-line which extends in the second region, to obtain a plurality of swipe sensor textile portions.

Preferred embodiments are the object of dependent claims.

Brief description of the drawings

The invention will now be described in greater detail, by way of example, with reference to the accompanying non limiting drawings, wherein like numerals denote like elements, and in which:

Figure 1 shows a repeating cell of a woven textile fabric according to a first embodiment of the invention;

Figure 2a shows a top view of the woven textile fabric of Figure 1 with warp capacitive sensing yarns;

Figure 2b shows a top view of the woven textile fabric of Figure 1 with warp and weft capacitive sensing yarns;

Figure 3 shows a repeating cell of a woven textile fabric, according to a second embodiment of the invention;

Figures 4-5 show, respectively, a bottom and a top view of the woven textile fabric of Figure 3;

Figure 6 shows a repeating cell of a woven textile fabric according to a third embodiment of the invention;

Figures 7-8 show, respectively, a bottom and a top view of the woven textile fabric of Figure 6;

Figure 9a shows a woven swipe sensor textile;

Figure 9b shows a section view of the textile of Figure 9a;

Figure 9c shows a piece of swipe sensor textile obtained from the woven textile of Figure 9a;

Figure 10 shows a model of a grounding scheme of the fabric of Figure 6 as used as a touch sensor;

Figure 1 1 is a circuitry scheme of an input stage of the textile fabric according to embodiments of the present invention;

Figure 12 is a circuitry scheme of a textile single-direction swipe sensor according to an embodiment of the present invention; and

Figure 13 is a circuitry scheme of a textile double-direction swipe sensor according to another embodiment of the present invention.

Detailed description of the drawings

Exemplary embodiments will now be described with reference to the enclosed drawings without intent to limit application and uses.

In the following description and figures, the wording "grounding" or "ground terminal" (GND), used for example in the wording "grounding grid", refers to any ground level of potential of an electric circuit, or to any other stable level of potential not necessarily being a ground level for the electric circuit.

In Figure 1 a repeating cell of a woven textile fabric according to a first embodiment of the invention is shown.

The woven textile fabric 10 of Figure 1 comprises a first set of electrically conductive, externally isolated yarns 22, and a second set of non-isolated conductive yarns 23.

The first and the second set of yarns 22, 23 are interlaced by a plurality of interlacing textile yarns, wherein some of the interlacing textile yarns are nonisolated conductive yarns 23 in order to form an electrical grounding grid with the non-isolated conductive yarns 23 of the second set of yarns.

Moreover, part of the interlacing textile yarns are conventional isolating textile yarns 24.

Therefore the interlacing textile yarn comprise both isolating and nonisolating yarns. In such a way an electrical grounding grid is formed.

Also, in the textile fabric 10 of Figure 1 , the electrically conductive, externally isolated yarns 22 of the first set of yarns 20 are separated by isolating textile yarns 24.

In the embodiment of Figure 1 , the first and the second set of yarns 22, 23 are warp yarns and the interlacing textile yarns 23, 24 are weft yarns.

In another possible embodiment of Figure 1 , the first and the second set of yarns 22, 23 are warp yarns and the interlacing textile yarns 22, 23, 24 are weft yarns.

Nevertheless, in an alternative embodiment, the first and the second set of yarns 22, 23 may be weft yarns and the interlacing textile yarns 23, 24 or 22, 23, 24 may be warp yarns.

In the textile fabric of Figure 1 , the first set of electrically conductive, externally isolated yarns 22, the isolating textile yarns 24 and the second set of non-isolated conductive yarns 23 form a single textile layer 20.

The electrically conductive, externally isolated yarns 22 of the first set of yarns are preferably core spun with a conductive center 25 and an isolating external surface 27.

The conductive core 25 of the electrically conductive, externally isolated yarns 22 of the first set of yarns is preferably made of a material chosen from steel, copper, silver or a conductive polymer. For example, the conductive core can be a copper monofilament. Preferably, the monofilament can be tick in the range 30-40 μιτι, more preferably 35 μιτι. According to another example, the conductive core can be a two copper monofilaments, in which the detection measure is based on the measure of the mutual capacitance of the two monofilaments with respect to each other.

The isolating external surface 27 of the electrically conductive, externally isolated yarns 22 of the first set of yarns is preferably made of at least one material chosen from cotton, polyester, polyurethane, propylene or another resin.

Referring to the linear mass density of the electrically conductive, externally isolated yarns 22, a core spun yarn can present a cotton, polyester, or viscose fiber blend in the range Ne 120/1 -Ne2/1 , preferably in the range Ne20/1 -Ne6/1 .

The non-isolated conductive yarns 23 are preferably made of steel, or copper, or of steel and/or copper twisted around cotton or of a steel and/or copper cotton blend. According to another embodiment, conductive yarns can be any resistive material without isolation, for example a thermoplastic textile yarn coated by a conductive material or with dispersed conductive impurities such as, but not limited to, carbon black, graphene, CNT, metallic impurities or a combination thereof. For example, embodiments of the invention include conductive yarns with carbon impurities in a 80-denier nylon 6,6 monofilament commercially know under the name RESISTAT F902, R080 MERGE series from Shakespeare Conductive Fibres®, or steel yarns from Bekaert.

Finally, the isolating yarns 24 are preferably made of a textile material chosen from cotton, polyester, nylon or functional derivatives thereof.

Moreover, the electrically conductive, externally isolated yarns 22 of the first set of form a sequence of capacitive elements, separated by isolating textile yarns 24, which may be ordinary or conventional textile yarns such as cotton or other textile materials, as depicted in Figure 2a-b which shows two possible embodiments of a top view of the woven textile fabric of Figure 1 . Figure 2a shows a woven textile fabric in which the electrically conductive, externally isolated yarns 22 are warp only.

According to this first embodiment, the swipe sensor textile can provide information along at least one direction, comprising along the direction orthogonal to the yarns 22, except along the direction parallel to the yarns 22. Figure 2b shows a woven textile fabric in which the electrically conductive, externally isolated yarns 22 are warp and weft.

According to this second embodiment, the swipe sensor textile can provide information along at least one direction, comprising along the direction orthogonal to the yarns 22, and along the direction parallel to the yarns 22. In other words, the swipe sensor textile can provide information along any direction on the plane of the textile.

The non-isolated conductive yarns 23 form a dense sequence of contacting yarns, electrically connected to an electrical ground reference to provide an electrical grounding grid.

As it will be better explained hereinafter, the above embodiment can be used in a one-directional textile sweep sensor.

A second embodiment of the invention is represented in Figure 3 and indicated as textile fabric 100.

In the textile fabric 100, the first set of electrically conductive, externally isolated yarns 22 form a first textile layer 120, and the second set of nonisolated conductive yarns 23 form a second textile layer 130, the second textile layer 130 being superimposed to the first textile layer 120.

In the embodiment of Figure 3, the first and the second textile layer 120, 130 are woven together by interlacing textile yarns.

In the embodiment of Figure 3, part of the interlacing textile yarns are nonisolated conductive yarns 23 in order to form an electrical grounding grid with the non-isolated conductive yarns 23 of the second set of yarns of the second textile layer 130 and part of the interlacing textile yarns are isolating textile yarns 24. Also for this embodiment, the first and the second set of yarns 22, 23 may be warp yarns and the interlacing textile yarns 23, 24 or 22, 23, 24 are weft yarns.

Nevertheless, in an alternative embodiment, the first and the second set of yarns 22, 23 may be weft yarns and the interlacing textile yarns 23, 24 or 22, 23, 24 may be warp yarns.

In Figure 4 a bottom view of the woven textile fabric of Figure 3 is represented in order to show the electric grounding grid formed by warp nonisolated conductive yarns 23 interlacing with weft non-isolated conductive yarns 23.

The bottom layer also shows isolating yarns 24 and electrically conductive, externally isolated yarns 22 which are isolated by virtue of their isolating external surface 27.

In Figure 5 a top view of the woven textile fabric of Figure 3 is represented. In this case, warp electrically conductive, externally isolated yarns 22 interlace with weft electrically conductive, externally isolated yarns 22 to form a sensor layer that can sense sweeping in two different directions, for example two mutually perpendicular directions.

A third embodiment of the invention is represented in Figure 6 and indicated as textile fabric 200.

In the textile fabric 200, the first set of yarns 22 form a first textile layer 120, and the second set of yarns 23 form a second textile layer 130.

The textile fabric 200 of Figure 6 further comprises a third set of structural isolating yarns 55 forming an intermediate textile layer 140 interposed between the first and second textile layer 120, 130.

Moreover, the textile fabric 200 of Figure 6 further comprises a plurality of structural isolating yarns 65 interlacing the first and second textile layer and the third intermediate layer 140 of structural yarns 55.

The intermediate textile layer 140 is an actual textile layer, made of ordinary textile yarns 55, 65, such as cotton, polyester or the like and mechanically woven together as any ordinary textile. In the embodiment of Figure 6, the second textile layer 130 is woven together by interlacing textile yarns, wherein part of the interlacing textile yarns are non-isolated conductive yarns 23 in order to form an electrical grounding grid with the non-isolated conductive yarns 23 of the second set of yarns of the second textile layer 130 and part of the interlacing textile yarns are isolating textile yarns 24.

In Figure 7 a bottom view of the woven textile fabric of Figure 6 is represented in order to show the electric grounding grid formed by warp nonisolated conductive yarns 23 interlacing with weft non-isolated conductive yarns 23.

The first textile layer 120 is woven together by interlacing textile yarns, wherein part of the interlacing textile yarns are electrically conductive, externally isolated yarns 22 that interlace with weft electrically conductive, externally isolated yarns 22 to form a sensor layer.

In Figure 8 a top view of the woven textile fabric of Figure 6 is represented.

In this case, electrically conductive, externally isolated yarns 22 of warp interlace with weft electrically conductive, externally isolated yarns 22 to form a sensor layer that can sense sweeping in two mutually perpendicular directions.

In any case, also for the embodiment of Figure 6, the first and the second set of yarns 22, 23 may be warp yarns and the interlacing yarns may be weft yarns. Nevertheless, in an alternative embodiment, the first and the second set of yarns 22, 23 may be weft yarns and the interlacing yarns may be warp yarns.

The textile embodiment of Figure 6 may be used in a two-directional textile sweep sensor.

Figures 9a-c show a possible method of producing a textile fabric such as the fabric above disclosed with reference to Figures 1 -8. The textile fabric according to the present invention can be produced by weaving resulting in a textile as shown in Figure 9a. The woven textile fabric comprises at least a set of electrically conductive, externally isolated yarns 22 for providing the swipe sensing property of the textile fabric.

The electrically conductive, externally isolated yarns 22 extend along at least a first region 31 of the fabric, said first region having a first weaving structure according to claim 1 ; yarns 22 also extend along at least a second region 32, said second region having a second weaving structure different from said first weaving structure.

More in detail, in said first region 31 , the electrically conductive, externally isolated yarns 22 are interlaced with non-isolated conductive yarns 23 and isolating textile yarns 24. In said second region 32, the electrically conductive, externally isolated yarns 22 are not interlaced with other yarns.

According to another step of the method of the present invention, the fabric as above is cut along at least a cut-line 30 in order to obtain a plurality of swipe sensor textile portions 1 1 , said cut-line 30 extending in said second region 32.

Once the swipe sensor textile portions 1 1 have been obtained, the electrically conductive yarns 22 extending in said second region of the swipe sensor textile portion 1 1 are connected to an input stage 70 which is preferably connected, according to the embodiments better described in the following, to a microcontroller 80. Part of the electrical insulation of yarns 22 may be removed to carry out the connection. Suitable microcontrollers are known in the art; a suitable microcontroller is disclosed in PCT/EP2016/068187.

The swipe sensor textile portion 1 1 together with the input stage 70 and the microcontroller 80, form a swipe-sensitive textile 500, 600.

In other words, the swipe sensor textile portion 1 1 is a piece of fabric suitable to be wearable and to sense capacitive variations. The swipe-sensitive textile 500, 600 is the textile that by comprising the swipe sensor textile portion 1 1 , the input stage 70 and the microcontroller 80, is able to detect the capacitive variation and to store and/or process the related data. Figure 10 shows an exemplary model of a grounding scheme of the fabric of Figure 6, as used as a textile touch or swipe sensor.

In particular, a woven textile fabric 200 is placed over the human skin 300, for example over a leg, with the grounding grid of non-isolated conductive yarns 23 contacting the human skin 300 and, consequently, the electrically conductive, externally isolated yarns 22 placed in a distal position from the human skin 300.

The conductive cores 25 of the electrically conductive, externally isolated yarns 22 of layer 120 are electrically isolated from each other.

However, when a relatively high capacity object such as a human finger 400 comes into contact with the layer of electrically conductive, externally isolated yarns 22, parasitic capacitive coupling phenomena may occur.

At the same time, the grounding grid of non-isolated conductive yarns 23 work as a barrier to damp the parasitic capacitance of the leg underneath the capacitive grid such that the finger touch is detectable.

Figure 1 1 is a circuitry scheme of an input stage 70 for processing signals coming from capacitive sensors.

In this example, the input stage 70 comprises an input terminal S, for receiving a signal coming from a capacitive sensor, such as the woven textile 10, and a ground terminal (GND). These two terminals are connected to electric contacts. The input stage comprises two further terminals SP, RP connected to a microcontroller 80.

The SP and RP terminals are separated by a resistance RTAU that may have values comprised in a range between 0.1 and 40 ΜΩ and the RP terminal is separated from the textile sensor by a resistance RESD that may have values comprised in a range between 0.01 and 1 ΜΩ that gives an Electro Static Discharge protection is in series with the textile sensor.

Turning to the capacitors of the circuit, for stabilization, a small capacitor Csi (100 pF - .01 F) from sensor Pin SP to ground GND improves stability and repeatability.

Another small capacitor Cs2 (20 - 400 pF), in parallel with the body capacitance, is desirable as it further stabilizes the readings.

In operation, the microcontroller 80 sends a reference signal to the SP (Send Pin) terminal, e.g. a Boolean signal in order to change a logic state. The RP (Receive Pin) terminal replicates this change of logic state with a time delay which is a function of the time constant of the Receiving Pin RP which in turn varies dominantly by the capacitance value of the sensor.

More in detail, the microcontroller 80 is controlled by a software that toggles the Send Pin SP to a new state and then waits for the Receive Pin RP to change to the same state as the Send Pin SP. A software variable is incremented inside a loop to time the state change of the Receive Pin. The software then reports the value of such variable, which may be in arbitrary units.

When the Send Pin SP changes state, it will eventually change the state of the Receive Pin RP. The delay between the changing of the state of the Send Pin SP and the changing of the state of the Receive Pin RP is determined by an RC time constant, defined by R ^* C, where R is dominantly the value of the resistance RTAU and C is the dominant capacitance at the Receive Pin RP.

If a human finger 400 (or any other capacitance provided object) is connected to the textile sensor, the value C of the capacitance at the Receive Pin RP is changed because the parasitic capacitance Cfi _nge r of the human finger 400 or of any other capacitance provided object) is added to the value C leading to new value C = C + Conger of the global capacitance sensed by the sensor.

This fact, in turn, changes the RC time constant of the system to R ^* C and, therefore, a different delay between the changing of the state of the Send Pin SP and the changing of the state of the Receive Pin RP is measured by the sensor due to the presence of the human finger 400 (or any other capacitance provided object), namely due to the interaction of the human finger 400 with the textile sensor.

Figure 12 is a circuitry scheme of a textile single-direction swipe sensor 500, according to an embodiment of the present invention.

The sensor 500 of Figure 12 comprises a textile fabric such as the textile fabric 10, previously described with reference to Figures 1 -2, the textile fabric 10 having a first set of electrically conductive, externally isolated yarns 22 and a second set of non-isolated conductive yarns forming an electrical grounding grid.

The first and second set of yarns form a single textile layer and are woven together by a plurality of isolating yarns.

The electrically conductive, externally isolated yarns 22 of the first set are arranged along an Y axis and are referenced for convenience with the numeral 22x for reasons that will be apparent hereinafter.

Each of the yarn 22x is connected to a corresponding input stage 70 as the one described with reference to Figure 1 1 .

In turn, each of the input stages 70 is connected to the microcontroller 80 with a respective Receive Pin i RP, where i ranges from 1 to N.

Therefore, if a human finger 400 (or any other capacitance provided object) is passed along the X direction in Figure 12, each of the Receive Pins RP, of the yarn 22x with which the human finger 400 interacts sense a different capacitance as measured by the variation of the RCi time constant of each of the system comprising the yarn 22x and the respective input stage 70.

In this way, a one-directional textile swipe sensor along the axis X may be provided.

Figure 13 is a circuitry scheme of a textile double-direction swipe sensor 600 according to another embodiment of the present invention.

The sensor 600 of Figure 13 comprises a textile fabric such as the textile fabric 100 of Figures 3-5 or textile fabric 200 of Figures 6-8 as previously described.

For example, the textile fabric 200 has a first set of electrically conductive, externally isolated yarns 22 and a second set of non-isolated conductive yarns forming an electrical grounding grid.

The first and second set of yarns form a single textile layer and are woven together by a plurality of isolating yarns.

The electrically conductive, externally isolated yarns 22 of the first set are arranged along two mutually perpendicular direction namely an Y axis and are referenced for convenience with the numeral 22x and an X axis and are referenced for convenience with the numeral 22y for reasons that will be apparent hereinafter.

Each of the yarns 22y is connected to a corresponding input stage 70 as the one described with reference to Figure 1 1 . In turn, each of the input stages 70 for the yarns 22y is connected to a microcontroller with a respective Receive Pin i RPi where i ranges from 1 to M.

Furthermore, each of the yarns 22x is connected to a corresponding input stage 70 as the one described with reference to Figure 1 1 . In turn, each of the input stages 70 for the yarns 22y is connected to a microcontroller with a respective Receive Pin i RPM+i where i ranges from M+1 to N.

In operation, if a human finger 400 (or any other capacitance provided object) is passed along the X direction in Figure 13, each of the Receive Pins RP, of the yarns 22x with which the human finger 400 interacts sense a different capacitance as measured by the variation of the RCi time constant of each of the system comprising the yarn 22x and the respective input stage 70.

If a human finger 400 (or any other capacitance provided object) is passed along the Y direction in Figure 13, each of the Receive Pins RPM+I of the yarns 22y with which the human finger 400 interacts sense a different capacitance as measured by the variation of the RC M+ time constant of each of the system comprising the yarn 22y and the respective input stage 70. In this way, a two-directional textile swipe sensor along the axis X and Y may be provided.

Of course, the microcontroller 80 of the sensor 600 can combine the information from both directional axis X and Y to detect a movement along a diagonal direction with respect to those axis.

The various embodiments of the invention have been described with reference to a woven textile fabric.

However, the same inventive concepts can be applied to a knitted textile or to a non-woven textile both suitable to implement the same idea of ground- shielded parasitic-capacitance-based touch-sensor fabric. For example, the textile fabric according to the present invention can comprise a non-woven textile suitable to implement a grounding layer and a woven textile or a knitted textile suitable to implement the capacitive grid touch-sensor.

While at least one exemplary embodiment has been presented in the foregoing summary and detailed description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration in any way. Rather, the foregoing summary and detailed description will provide those skilled in the art with a convenient road map for implementing at least one exemplary embodiment, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope as set forth in the appended claims and their legal equivalents.