Abstract: A method for knitting a garment having a tubular form, including knitting at least one conductive textile electrode on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive yarns, and knitting the electrode integrally within the tubular form, using a conductive yarn, in addition to the non-conductive yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment Lk, using feeder Fi and starting at needle D1; and knitting line segment Lk+1, using the next feeder and start stitching the first float-loop at needle D1+s where 0<s<y. The tubular form has a preconfigured 10 knitting density, wherein the electrode has a knitting density that is higher than the preconfigured knitting density of the tubular form.

Abstract: A method for knitting a garment having a tubular form, including knitting at least one vertical conductive textile trace on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive base yarns, and knitting the vertical conductive textile trace integrally within the tubular form, using a conductive yarn, in addition to spandex yarns, but not the base yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment Lk, using feeder Fi and starting at needle D1; and knitting line segment Lk+1, using the next feeder and start stitching the first float-loop at needle D1+s where 0<s<y.

Abstract: A connector-and-cable assembly, including an electronic connector, such as a HDMI connector, having an outlet section and a multiplicity of elastic conductive stripes. Each of the elastic conductive stripes is conductively connected, at a first end, to a respective preconfigured outlet pin of the electronic connector. The second end of each of the elastic conductive stripes is preconfigured to operatively attach to a respective sensor, such as a textile electrode of a smart garment. Typically, at least one of the elastic conductive stripes is a textile based conductive stripe.

Abstract: According to the teachings of the present invention there is provided an elastic smart garment. The garment includes an elastic tubular form having variable elasticity and at least one conductive textile electrode, for sensing electrical vital signals, such as a clinical level ECG signal. The garment further includes at least one elastic and loose conductive stripe, having a first end and a second end. The first end of the at least one conductive stripe is securely attached to a respective conductive textile electrode, and the second end of the at least one conductive stripe is operatively connected with a processor. The elasticity and looseness of the at least one conductive stripe is configured to prevent a pulling force from being applied to the respective conductive textile electrode, when the garment is stretched. When a conductive stripe is stretched by up to 15%, its resistance increases by less than 25%.

Abstract: A method for stabilizing the physical dimensions and positioning of at least one selected textile region of a knitted garment. The method includes producing the garment including a conductive textile electrode, rigidifying the at least one selected textile region and knitting a preconfigured region proximal to the at least one selected textile region with a lower knitting density than the preconfigured density of the tubular form. The invention further provides a garment having a tubular form, knitted by a seamless knitting machine with base-yarns. The garment includes at least one conductive textile electrode. The garment further includes at least one preconfigured region in proximity to the at least one selected textile region, having a lower knitting density than the preconfigured density of the tubular form and the at least one selected textile region.

Abstract: A connector-and-cable assembly, including an electronic connector, such as a HDMI connector, having an outlet section and a multiplicity of elastic conductive stripes. Each of the elastic conductive stripes is conductively connected, at a first end, to a respective preconfigured outlet pin of the electronic connector. The second end of each of the elastic conductive stripes is preconfigured to operatively attach to a respective sensor, such as a textile electrode of a smart garment. Typically, at least one of the elastic conductive stripes is a textile based conductive stripe.

Abstract: A garment that includes textile ECG-arm-electrodes (110LA and 110RA), such as knitted electrodes, wherein the textile ECG-arm-electrodes are located within the garment such that when the garment is worn, the textile ECG-arm-electrodes are situated adjacent to the bodily skin overlaying the outmost region of the Pectoralis major muscle, proximal to the shoulder muscle. Preferably, the positioning of the textile ECG-arm-electrodes, within the garment, is designed to match the size of the garment.

Abstract: According to the teachings of the present invention there is provided a knitted smart garment. The garment includes a tubular form having variable elasticity and at least one conductive textile electrode for sensing an electrical vital signal, such as a clinical-level ECG signal. The garment further includes at least one elastic and loose conductive stripe, having a first end and a second end. The first end of the at least one conductive stripe is securely attached to a respective conductive textile electrode, and the second end of the at least one conductive stripe is operatively connected with a processor. The elasticity and looseness of the at least one conductive stripe is configured to prevent a pulling force from being applied to the respective conductive textile electrode, when the garment is stretched.

Abstract: A method for stabilizing the physical dimensions and positioning of at least one selected textile region of a knitted garment. The method includes producing the garment including a conductive textile electrode, rigidifying the at least one selected textile region and knitting a preconfigured region proximal to the at least one selected textile region with a lower knitting density than the preconfigured density of the tubular form. The invention further provides a garment having a tubular form, knitted by a seamless knitting machine with base-yarns. The garment includes at least one conductive textile electrode. The garment further includes at least one preconfigured region in proximity to the at least one selected textile region, having a lower knitting density than the preconfigured density of the tubular form and the at least one selected textile region.

Abstract: A method for substantially reducing the elasticity of at least one selected textile region of a garment. The method includes producing the garment including a conductive textile electrode and rigidifying the at least one selected textile region. The rigidifying process includes applying rigidifying matter onto or into the at least one selected textile region. The at least one selected textile region is selected from the group consisting of a conductive textile electrode and a region of the garment situated between two adjacent textile electrodes. The invention further provides a garment having a tubular form, knitted by a seamless knitting machine with base-yarns. The garment includes at least one conductive textile electrode, composed of multiple knitted line segments, each knitted with a conductive yarn and a spandex yarn, wherein the spandex yarn and at least one base-yarn are knitted continuously.

Abstract: A monitoring system for monitoring physiological parameters of a living being. The monitoring system includes a smart garment, a processing unit and a docking station. The docking station enables quick and easy engagement/disengagement of the processor. The docking station is electrically connected to sensors of the smart garment to thereby provide the sensed data to the processor that is docked thereon. The processor is adapted to obtain some or all of the sensed data via a communication interface such as HDMI. The docking station and the smart garment may be interconnected using complementary conductive snap buttons. The docking station may include at least one through opening formed in its back wall, to thereby enable wired operational communication between the processing unit and a respective additional external sensor. The docking station may include a defibrillator protection device to protect the monitoring system from an electric current or voltage surge.

Abstract: A method for substantially reducing the elasticity of at least one selected textile region of a garment. The method includes producing the garment including a conductive textile electrode and rigidifying the at least one selected textile region. The rigidifying process includes applying rigidifying matter onto or into the at least one selected textile region. The at least one selected textile region is selected from the group consisting of a conductive textile electrode and a region of the garment situated between two adjacent textile electrodes. The invention further provides a garment having a tubular form, knitted by a seamless knitting machine with base-yarns. The garment includes at least one conductive textile electrode, composed of multiple knitted line segments, each knitted with a conductive yarn and a spandex yarn, wherein the spandex yarn and at least one base-yarn are knitted continuously.

Abstract: A method for knitting a garment having a tubular form, including knitting at least one vertical conductive textile trace on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive base yarns, and knitting the vertical conductive textile trace integrally within the tubular form, using a conductive yarn, in addition to spandex yarns, but not the base yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment Lk, using feeder Fi and starting at needle D1; and knitting line segment Lk+1, using the next feeder and start stitching the first float-loop at needle D1+s where 0<s<y.

Abstract: A method for knitting a garment having a tubular form, including knitting at least one conductive textile electrode on a machine having N participating feeders and M needles. The method includes the steps of continuously knitting the tubular form with one or more flexible non-conductive yarns, and knitting the electrode integrally within the tubular form, using a conductive yarn, in addition to the non-conductive yarns. The conductive yarn is knitted in a float-loop form by knitting a stitch and skipping over y needles, as follows: repeatably knitting a line segment Lk, using feeder Fi and starting at needle D1; and knitting line segment Lk+1, using the next feeder and start stitching the first float-loop at needle D1+s where 0<s<y. The tubular form has a preconfigured 10 knitting density, wherein the electrode has a knitting density that is higher than the preconfigured knitting density of the tubular form.