The invention is from the field of wearable devices. Specifically the invention relates to wearable devices that comprise computing and communication capabilities.
Smartwatches are wristwatches belonging to a group of wearable devices that are widely sold and worn by users around the world. In addition to the traditional function of keeping time, smartwatches are today essentially portable computing and communication devices that are worn on a user's wrist. Smartwatches are available in a very large variety of models that offer an even larger variety of functions. In different embodiments they comprise sensors to monitor, for example, physiological functions of the user, environmental conditions, and GPS tracking. Most models comprise communication functions that enable short range communication through protocols such as Bluetooth and/or long range communication via the internet or cellular networks. The latest developments in the art are centered around providing all functions available on smartphones on wrist worn computing systems.
Ultrasonic functionality is provided on some models of smartphones for distance measuring and gesture recognition applications. However use of ultrasonic for medical imaging purposes is currently not one of the functionalities presently available on any type of wearable device including smartwatches.
It is a purpose of the present invention to provide a wearable device that comprises an ultrasonic system that provides full capability of generating medical images.
Further purposes and advantages of this invention will appear as the description proceeds.
The invention is a wearable device, which comprises an ultrasonic system. The ultrasonic system comprises a substrate that comprises an ultrasonic transducer array and accompanying circuitry. The wearable device is configured to produce useful ultrasonic images.
Embodiments of the wearable device comprise components configured to provide computing and communication functionalities.
In embodiments of the wearable device the wearable device is a smartwatch.
In embodiments of the wearable device the substrate is manufactured as an integral component that is permanently attached to the wearable device.
In embodiments of the wearable device the substrate is manufactured as a separate component that is configured to be attached to and detached from the wearable device.
In embodiments of the wearable device the surface of the smart device to which the substrate is attached may have any shape and curvature.
In embodiments of the wearable device the back surface of the substrate has a shape and curvature to match that of the surface of the smart device to which it is attached.
In embodiments of the wearable device the ultrasonic transducer array has a cross-sectional shape in a plane perpendicular to the substrate that is one of concave and straight.
In embodiments of the wearable device the substrate comprises an application specific integrated circuit (ASIC) comprising at least some of the components of an analog frontend (AFE), a beamformer with frontend processing, and a backend processing block, which are the three processing blocks that are present in all ultrasonic systems.
In embodiments of the wearable device at least some of the beamforming and/or image processing is carried out on the wearable device using either dedicated circuitry or circuitry that includes existing components of the circuits on the wearable device that perform other functions.
In embodiments of the wearable device electrical power transmission between the electronic circuit on the substrate of the ultrasonic system and the wearable device is done by a wired connection.
In embodiments of the wearable device images and/or raw data are communicated between a transmitter ASIC on the substrate of the ultrasonic system and the wearable device by one of a direct wired connection and a wireless connection.
In embodiments of the wearable device electrical power is supplied to the electronic circuit and transducer array on the substrate of the ultrasonic system from a battery in the wearable device.
In embodiments of the wearable device images and/or raw data are communicated by the transmitter ASIC on the substrate of the ultrasonic system either wirelessly or via the communication capabilities of the wearable device to a remote location where they can be stored, displayed, and analyzed by medical practitioners.
In embodiments of the wearable device processed images are displayed on a screen on the smart device.
Embodiments of the wearable device are configured to provide ultrasonic images and data related to the following medical conditions:
In embodiments of the wearable device the number of transducer elements is above 2, e.g. 64, 128, 256, and more.
Embodiments of the wearable device comprise at least one of: a backing layer, an acoustic matching layer, and a lens.
All the above and other characteristics and advantages of the invention will be further understood through the following illustrative and non-limitative description of embodiments thereof, with reference to the appended drawings.
The present invention is a wearable device, which comprises an ultrasonic system comprised of an ultrasonic transducer array and accompanying circuitry thereby providing the device with the capability to produce useful ultrasonic images for use in monitoring medical conditions.
The ultrasonic transducer array and accompanying circuitry can be mechanically supported in many ways such as: by using silicon processing techniques to create them on a silicon substrate; encapsulating them in epoxy; and using techniques developed to manufacture printed circuit boards on glass epoxy, ceramic, or insulated metal substrates. Herein the term ‘substrate’ will be used in a generic sense to refer to any of these or any other method known in the art to mechanically support electronic circuits and their components.
The ultrasonic transducer has a backing layer, a matching layer and an array composed of at least two transducer elements. In embodiments of the invention the number of elements is above 2, e.g. 64, 128, 256, and more. The elements are arranged in rows and columns and the accompanying circuitry is configured to create a phased array.
Herein the invention is described in depth in connection with a smartwatch as a specific example of wearable device; however the invention can be embodied in connection with other wearable devices, such as a detachable unit mounted on a belt or strap fastened around a user's waist, thigh, or ankle.
In some embodiments the display and communication functions as well as components of the processing circuit of the smartwatch (or other wearable device) are utilized are however they as well as the other functionalities of the devices are not described herein since they are not relevant to the invention. For purposes of the invention the smartwatch per se is prior art. The essence of the invention is the combination of an ultrasonic system with any smartwatch.
In a first embodiment (shown in
In embodiments of the invention a backing layer is added between the transducer array 14 and the substrate 12 in order to absorb back emitting ultrasonic waves from the transducer array 14. The backing layer can be formed, for example, from a mixture of an epoxy and metallic powder. The addition of the metallic powder, e.g. tungsten, to epoxy, e.g. Epo-Tek 301, increases the attenuation and acoustic impedance which are required for good absorption. Some types of epoxy that include metallic filler, for example Epo-tek EJ2189, are also suitable to achieve this end. The transducer array 14 can also be covered by an acoustic matching layer and a lens in order to provide protection in addition to beam focusing and acoustic matching. A lens formed from a low attenuation, low speed of sound, acoustically matched silicon material, such as but not restricted to, Sylgard 170 can serve both the focusing and acoustic matching functions. Backing layers, acoustic matching layers, and lenses are common features of ultrasonic systems and can be implemented in many different ways that are known in the art.
The smartwatch case can have any shape and curvature, e.g. round, square, rectangular, or octagonal. The surface of the substrate on which the ultrasonic system is constructed and that is attached to the smartwatch case is shaped accordingly and the ultrasonic transducer array has a radius of curvature that is required for the scan procedure, i.e. its cross-sectional shape in a plane perpendicular to the substrate can be either concave or straight.
In one embodiment ultrasonic system 10 or 20 comprises substrate 12 on which is created an ultrasonic transducer array 14 and an application specific integrated circuit (ASIC), which comprises at least some of the electronic components the ultrasonic system 10 needs in order to operate. In other embodiments only part of the beam forming and/or processing required to produce the final images is carried out by circuitry on substrate 12 and the remainder of the processing is carried out using circuitry in the smartwatch. At least some of the processing can be done at a remote location. For example all or a part of the raw data from ultrasonic transducer array 14 can be sent by a transmitter ASIC on substrate 12 to a receiver on smartwatch 18 for further processing using either completely dedicated circuitry or circuitry that makes use of existing components of the circuits on the smartwatch that perform other functions.
In one embodiment, described below, the ASIC on substrate 12 comprises all of the three distinct processing blocks that are present in all ultrasonic systems: the analog frontend (AFE), the beamformer with frontend processing, and the backend. However, as described above, other embodiments of this ASIC are possible, depending on how much of the beamforming and processing is carried out on the substrate 12, the smartwatch 18, or at a remote location.
The AFE is a highly specialized system for ultrasonic applications that comprises components to handle the large dynamic range of the transducer array receive signals, which typically are in the frequency range of 800 Khz to 20 Mhz.
The beamformer consists of two parts that are time synchronized and continuously pass timing, position, and control data to each other.
(1) The transmit beamformer (or Tx beamformer) is responsible for initiating scan lines and generating the timed pulse string to the transducer array elements to set the desired focal point in the structure. The Tx beamformer steers and generates a timed, digital pulse string that gets externally converted into high-voltage pulses for the transducer array. The delay is calculated in real-time, based on the required instantaneous location of the focused ultrasonic beam for the given scan line.
(2) The receive beamformer (or Rx beamformer) is responsible for receiving the echo waveform data from the analog frontend, and collating the data into representative scan lines through filtering, windowing, summing, and demodulation. The Rx beamformer parses the raw transducer array Rx data to extract and assemble ultrasonic scan lines.
The backend processing block typically includes at least one of B-mode, M-mode, Doppler, and color flow processing functions. These functions operate simultaneously and perform a variety of actions to produce images. The backend then cleans and adjusts the images to suit the requirements of the sonographer and the display being used, and stores, displays, and transmits static and video outputs.
In embodiments of the smart device, the processed images can be displayed on the screen of the smartwatch and/or transmitted via the communication capabilities of the smartwatch to a remote location where they can be stored, displayed, and analyzed by medical practitioners.
The ultrasonic system 10 or 20 may be comprise a power source. In one embodiment the system uses the battery of the smartwatch to provide power for the transducer array and ASIC circuit. Conversion of voltage or current (as the case may be) is well known in the art. For example Texas Instruments TL497ACN components can convert the input voltage from a smartwatch to the excitation voltage required by the ultrasonic transducer array.
The power supply to system 10 or 20 is sufficient to allow non-continuous measurements, e.g. to provide scans of inter alia an internal organ such as a vein, an artery, a heart, a lung, a kidney, and even the intracranial pressure. Semi-continuous monitoring can be performed by taking scans every few minutes to make measurements of, for example, blood flow, heart beat, or the level of liquid in the lungs.
Power transmission between the electronic circuit on substrate 12 of the ultrasonic system 10 and the smartwatch 18 is done by a wired connection and data is communicated between the substrate 12 and smartwatch 18 either by a direct wired connection or wirelessly by a well-known protocol, for example, Bluetooth. The electrical interface between ultrasonic system 10 and smartwatch 18 is comprised of a socket 22 (see
The ultrasonic transducer array 14 is composed of transducer elements, which can be made from different materials such as, for example, Piezo, PZT, or films, PVDF, PMN-PT, PMN-XX, PIN-PMT-XX where the XX is for several derivatives of the materials, and metals. Ultrasonic transducer array 14 is manufactured using know techniques, for example Silicon based substrates, CMUT (Capacitive Micromachined Ultrasonic Transducer Arrays), PMUT (Piezoelectric Micromachined Ultrasonic Transducer arrays), MEMS (Microelectromechanical Systems), and NEMS(Nanoelectromechanical Systems. The transducer elements can be arranged to form a linear array, a focused array, a multi-dimensional array, i.e., a 1.5D, 2D and 3D array. The elements may be implemented in several straight or curved rows and columns to form arrays of different shapes that can be constructed on a plane, a convex, or a concave surface.
In addition to the examples given above of some of the types of scans that can be carried out using system 10 or 20, a very limited list of some applications for which the invention is particularly well suited follows:
Although embodiments of the invention have been described by way of illustration, it will be understood that the invention may be carried out with many variations, modifications, and adaptations, without exceeding the scope of the claims.
Number | Date | Country | Kind |
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255098 | Oct 2017 | IL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IL2018/051087 | 10/7/2018 | WO | 00 |