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healthcareandlifeblogs · 17 days ago

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U.S. Intraoperative Neuromonitoring with Latest Healthtech Innovations by 2032

Intraoperative Neuromonitoring (IONM) has become an integral part of surgical procedures involving the nervous system in the United States. It plays a pivotal role in protecting neural structures during complex operations, such as spinal, brain, vascular, and ENT surgeries. By continuously assessing the functional integrity of neural pathways, IONM assists surgeons in minimizing the risk of postoperative neurological deficits.

Read Full Research Report: https://www.alliedmarketresearch.com/us-intraoperative-neuromonitoring-market

The IONM field in the U.S. has seen substantial growth, supported by increasing awareness, specialized training, and regulatory advancements. With the growing complexity of surgical interventions and the heightened demand for precision and safety, the integration of healthtech innovations into IONM has revolutionized the way neurophysiological monitoring is conducted in the operating room.

Advanced AI and Machine Learning Integration

One of the most promising developments in IONM is the integration of artificial intelligence (AI) and machine learning (ML). These technologies enhance the accuracy of signal interpretation by reducing false positives and negatives, thereby improving intraoperative decision-making. Real-time analytics powered by AI algorithms can detect subtle changes in neural signals and alert surgical teams to potential complications before irreversible damage occurs.

Several healthtech startups and established medical device companies are developing AI-powered platforms that automate signal acquisition, reduce operator dependency, and provide predictive analytics. These platforms can also learn from thousands of past procedures to improve response accuracy, making surgeries safer and more efficient.

Remote Monitoring and Tele-IONM

Telemedicine is rapidly transforming healthcare delivery, and IONM is no exception. Tele-IONM enables remote neurophysiologists to monitor surgeries in real-time from off-site locations. This not only addresses the shortage of trained professionals in certain regions but also allows 24/7 coverage for hospitals and surgical centers.

Cloud-based platforms equipped with end-to-end encryption ensure secure data transmission and real-time collaboration between the surgical team and remote monitoring personnel. These systems also support multi-case monitoring and centralized data storage, which facilitates postoperative reviews and quality assurance.

Wearable and Wireless Technologies

Another breakthrough in IONM is the emergence of wearable and wireless monitoring systems. Traditional monitoring setups often involve cumbersome wiring and bulky equipment, which can be disruptive during surgery. New wireless electrodes and compact signal processors reduce clutter in the operating room and enhance mobility for surgeons and staff.

Moreover, wearable EEG and EMG sensors offer high fidelity in signal acquisition while maintaining patient comfort and reducing setup time. These innovations streamline workflow and reduce the margin of error, especially in high-risk procedures.

Real-time 3D Visualization and Augmented Reality (AR)

Advanced visualization tools are now being integrated with IONM systems to provide surgeons with real-time 3D maps of neural pathways. Augmented Reality (AR) overlays can project neural structures onto the surgical field, allowing precise navigation and improved spatial awareness.

This fusion of IONM and AR is particularly valuable in complex spinal and brain surgeries where the margin for error is minimal. Visual cues synchronized with neurophysiological data offer an enhanced perspective that significantly reduces the risk of nerve damage.

Regulatory and Training Improvements

To support these technological advancements, regulatory bodies in the U.S. such as the American Society of Neurophysiological Monitoring (ASNM) and the Centers for Medicare & Medicaid Services (CMS) have updated guidelines to include tele-IONM and AI-assisted monitoring. Furthermore, medical schools and training programs are incorporating simulation-based IONM modules, ensuring that future neurophysiologists are proficient with emerging technologies.

Conclusion

The future of intraoperative neuromonitoring in the U.S. is being reshaped by cutting-edge healthtech innovations. From AI-driven analytics and telemedicine to wearable sensors and AR integration, these advancements are not only enhancing surgical outcomes but also redefining the standards of neurosurgical safety. As these technologies become more accessible and widely adopted, patients across the country can expect safer, more precise, and more efficient surgical care.

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mindbodydevices · 1 year ago

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shellywrighttech · 3 years ago

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Smart Health Products Market Size, Share – Global Outlook and Forecast 2022-2028

Introduction:

Information technology towards smart healthcare, the concept has increased in the internet of things, big data, artificial intelligence, and cloud computing transforming the traditional medical system into smart efficient and convenient for the healthcare sector. Moreover, smart healthcare includes multiple participants like doctors, patients, hospitals, and research institutions. It helps the patient for various aspects such as smart parking, data maintenance, card facility for hospitals, medical assistance through virtual assistance, and image visualization for the smooth experience and avoiding time consumption. According to the study of Springer’s article, after the covid-19 pandemic pushes healthcare for the technological growth and Wireless Sensor Networks (WSN) become very efficient towards tracking systems, medical treatment. Moreover, to analyse the data applications for healthcare electromyogram (EMG), electrocardiogram (ECG) and electroencephalogram (EEG), magneto encephalogram (MEG), galvanic skin response (GSR), electrooculography (EOG).

Segmentation:

Global smart health products market is segmented into product type, Application, users, and region. Based on type market is segmented into electronic health record, RFID, telemedicine, and others. Based on application market is segmented into health data storage, monitoring and treatment, and inventory management. Based on user market is classified into hospitals, home health care, and others. Based on region, skincare products market is segmented into North America, Europe, Asia Pacific, Latin America, Middle East and Africa.

Market dynamics and factors:

The increasing demand for smart health products seems long-term scope and helps in harmful disease efficient way which drives the growth of the global smart healthcare products market. In addition, the rising adoption of smartphones, digital technology, cloud-based electronic record, makes entire health operations smooth by sharing data and easy access to launch new products. For instance, Johns Hopkins Hospital, USA using a smart command center that helps manage beds, dispatch ambulances and allocate staff. It also helps in waste management and manages supplies. Furthermore, the high cost of the products and lack of skilled professionals to work on electronic healthcare products hamper the growth of the market. Furthermore, smart healthcare products have opportunities across the country after the pandemic situation. Telemedicine, e-commerce, drones, robots, and artificial intelligence will transform healthcare that is performed by humans to reduce variability, cost, and error. Moreover, drone companies have started working to deliver blood, vaccines, snakebite serum, and other medical supplies. For instance, Zipline has been developing a drone service known as Zips, which can deliver 150 blood packets a day. Drone manufacturer Flirtey also worked on demo delivery in the U.S. of the emergency testing products. Hence, these opportunities have been expected to rise for the forecasted period of the overall market.

Request Free Sample Report @ https://statisticalinsights.com/sample-request/11-Smart-Healthcare-Products

Regional analysis:

Geographically, Global health product market is segmented into North America, Europe, Asia Pacific, Middle East and Africa.

North America dominates the market due to increasing demand for electronic inventory management solutions, RFID, and rising healthcare expenditure by individuals in the region. Efficient and better healthcare quality to the population has increased the demand for smart healthcare devices and information electronically.

Europe region captured the second largest market growth of smart health products, countries such as U.K. and Germany believed to be the major countries witnessing smart healthcare products. This augmented demand is attributed to the rising in this region. Smart Health innovation, continuous developments in ICT, e-location technology, healthcare infrastructure, and broadband data connectivity encourages both the public and the private sector to explore the possibilities of Smart Health.

The Asia Pacific owing to a quickly evolving smart health products market on a digital platform. The favourable government initiatives to improve the healthcare sector are helping to boost the growth of products. For instance, India launches the world’s biggest healthcare program called Modicare which is based on digitalized healthcare products like telemedicine and mHealth.

In the Middle East and Africa, the government has taken some smart digital healthcare initiatives, The investors investing in medical services but due to government pressure and laws affecting the future expansion of the smart healthcare market and hindering rapid in the region.

Key players:

Medtronic

Honeywell international inc.

Becton, Dickinson and company

AirStrip

Olympus Corporation

Flirtey

Flyzipline

Access Complete Report @ https://statisticalinsights.com/main-report/11-Smart-Health-Products-Market.php

Key industrial development:

04-06-2021: Samsung India has added new Samsung Smart Healthcare centres at Government hospitals across the country, as part of its citizenship initiative, helping Covid Warriors perform faster Covid-19 diagnosis. Samsung ramped up the program to add 56 new Samsung Smart Healthcare centres in hospitals across 19 states, contributing to Covid management.

21-06-2021: Japan plans to launch paper documents indicating vaccination status by the end of July to allow its residents to travel internationally. Moreover, South Korea has rolled out a digital health pass, in the form of a smartphone app known as ‘COOV’ and developed by Blockchain Labs, with the backing of the Linux Foundation.

02-06-2021: Huawei Launches Huawei Watch 3 Series Powered by Harmony OS 2. It has multifunctional features, additionally this watch can monitor skin temperature with a new high-precision temperature sensor. It also supports fall detection and SOS functions so users can monitor and manage their health in real time.

Continue…

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The Statistical Insights is one of the largest collections of market research reports from numerous publishers. We have a team of industry specialists providing unbiased insights on reports to best meet the requirements of our clients. We offer a comprehensive collection of competitive market research reports from a number of global leaders across industry segments. The research reports by The Statistical Insights, are produced by experienced market researchers. Reports will have in-depth analysis about-

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chloedecker0 · 3 years ago

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SMART HEALTH PRODUCTS MARKET RESEARCH, FUTURE TRENDS, OPPORTUNITIES AND DEEP ANALYSIS 2028

Introduction:

Segmentation:

Market dynamics and factors:

Request Free Sample Report @ https://statisticalinsights.com/sample-request/11-Smart-Healthcare-Products

Regional analysis:

Geographically, Global health product market is segmented into North America, Europe, Asia Pacific, Middle East and Africa.

Key players:

Medtronic

Honeywell international inc.

Becton, Dickinson and company

AirStrip

Olympus Corporation

Flirtey

Flyzipline

Access Complete Report @ https://statisticalinsights.com/main-report/11-Smart-Health-Products-Market.php

Key industrial development:

Continue…

About The Statistical Insights

[email protected]

Phone: + (210) 775-2636 (USA) + (91) 853 060 7487

Website @ https://www.statisticalinsights.com/

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anilinnovation-blog1 · 6 years ago

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PhD Assistance-A Necessary Support for the Technical Research Scholars

The guidance for the research student becomes rudimentary activity for the technical PhD Assistance. The project has its own technical involvement including coding and practical application of the theoretical knowledge.

The complete Research Project, especially Technical, incorporates hardware and software. Since all the components are the important for the technical research paper and in this topic selection is the most vital and it should make sense in the logical point of view in the prospect of the technology used to make the project live. Here PhD Assistance required to interrelate the theory and the practical.

The proceeding of the projects brings more idea by asking the following questions:

1. Why I want to perform a particular technical activity? Means what benefits I would get to accomplish the task.

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There are following steps are used to start any technical research projects:

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Resource management and allocation in Device to Device communication for QoS provisioning

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COGNITIVE RADIO- A SOLUTION TO ENHANCE FUTURE PERFORMANCE of cellular network

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FinFETs: From Devices to Architectures

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Retinal Area Detector From Scanning Laser Ophthalmoscope (SLO) Images for Diagnosing Retinal Disease.

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chrishurstabs · 8 years ago

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A smart nanofiber shirt gives this IndyCar champ a competitive edge

Tony Kanaan in action at the 2017 Firestone Grand Prix.

Image: 2017, Scott R LePage/LAT Images

When IndyCar champ Tony Kanaan takes the wheel of his race car, his performance depends on more than just driving skill. Forces of up to 5 Gs five times the force of gravity push on his bones as he whips around turns, driving at speeds as fast as 220 mph in pursuit of his next win, so he needs to be in the right shape to handle the road.

Those conditions put a ton of pressure physical and psychological on the driver. After a few races last season, Kanaan’s team noticed he was dealing with those stressors in a very specific way: gripping the steering wheel way too hard.

SEE ALSO: Witness the strange beauty of the first self-driving race car

“My crew was asking me, ‘Why are you squeezing the steering wheel so hard?'” Kanaan said in a phone interview. “‘Why are you wasting your energy?'” He was able to remedy the problem quickly once it was pointed out, freeing up valuable effort better spent elsewhere.

Imagine if your Fitbit’s tracking power was amped up and spread out across your whole torso.

Kanaan’s team was only able to notice his hard grip after analyzing electromyogram (EMG) readings, which measures the electrical activity of muscles. And they didn’t get that data from an Apple Watch or Fitbit, but instead from a highly sophisticated wearable: a race shirt made out of “biosensing” fabric. The fabric, called Hitoe, can pick up the electrical signals produced by his body and convert them to data, including heart rate, electrocardiogram (aka ECG, which measures heart activity), the aforementioned EMG, and more.

The data helps Kanaan fine-tune his body’s performance the same way his crew adjusts his car. Now, imagine that same tech adopted widely, with patients wearing biosensing clothes so doctors can monitor patients’ recovery in real time. That’s the promise of Hitoe.

But first it needs to prove itself with IndyCar.

Training with tracking power

Kanaan is the only driver on the IndyCar circuit who has access to Hitoe. That’s thanks to his sponsor, NTT Data, a subsidiary of Japanese tech conglomerate, NTT (probably best known for the wireless carrier NTT Docomo, another subsidiary).

“When they introduced the shirt, I was like, whoa,” said Kanaan. “My biggest challenge has always been to figure out how to feel better in the car and I don’t get to drive it every day. So what can I do to find out how to be a better fit to drive the car?”

Imagine if your Fitbit’s tracking power was amped up and spread out across your whole torso. Using those insights, Kanaan and his team develop workout regimens so he can push his body to mimic the same conditions he’ll face in the cockpit of his race car. So, if Kanaan’s heart rate pumps up to 160 beats per minute (bpm) in the middle of a race, his trainer will push his performance up to that same level in the gym.

“I use it all the time outside the car,” said Kanaan. “The shirt doesn’t give me more talent you’re not gonna put it on and become Superman or LeBron James.” But it does help him find the best ways he can push his performance to new levels.

One layer, lots of insights

Hitoe comes from a Japanese term that means “one layer,” because the sensors are integrated directly into a nanofiber fabric. The design was created by NTT and Toray Industries, a global textile manufacturer.

The fabric’s ability to track heart rate and ECG information is a big deal for Kanaan. His car is packed with state-of-the-art equipment to monitor its performance but the Hitoe tech is the first time he has ever been able to track his own body in real time, because the signal from other monitors interfered with the telemetry system of the car.

“When they introduced the shirt, I was like, whoa.” – Tony Kanaan

This is the third season Kanaan is wearing the Hitoe shirt. The first year, the tech was applied in patches sewn on to Kanaan’s Nomex fireproof racing suits, which all drivers are required to wear.

Kanaan with his number 10 NTT Data car.

Image: NTT DATA

Those sewn-on patches on the fire suit were just the start.

“The project matured with Tony because he found a lot more value with us exploring his muscle activity,” said Adam Nelson, the VP of Healthcare and Life Sciences for NTT Data. Nelson said the focus of the project was on capturing even more specific muscle-performance data in 2016, with a complicated system that fed the data collected from Kanaan’s body into the same system that reported how his car was performance.

Kanaan is wearing an advanced version of the Hitoe shirt for the 2017 IndyCar season, his 20th year in the sport, which is now underway. Instead of only using patches sewn into his fire suit, the shirt has been “dyed” with the sensor tech, putting it closer to his skin for more complete coverage.

Off the track

Giving champion race car drivers a performance edge isn’t the only reason NTT developed Hitoe. Nelson and his team have much larger ambitions for the smart fabric.

“We’ve always called our experiment from track to treatment, because what we’re learning on the track we want to bring out into the healthcare system,” he said.

The fabric’s potential for physical therapy and outpatient recovery could be its best use. Nelson imagines Hitoe being given to patients to make recovery from injury and surgery a more convenient experience, since the data it collects can be monitored remotely from anywhere.

Insurance companies already give customers the option of using smart devices like the Apple Watch to gain more insights about their health, which could personalize plans and cut premium costs, though more connectivity and data exacerbate privacy concerns.

Since Hitoe is just like any other shirt, it could be much more convenient for outpatient treatment.

Image: USa today sports

Kanaan is excited to be part of the project to develop the Hitoe system beyond just the benefits he’ll reap on the track from the data collection.

“For me, the biggest thing is to be able to help people outside racing, with rehab and health care,” he said. “I lost my dad to cancer, and I was in with him in the hospital for four years so I know how depressing that can be.”

Hitoe purely an IndyCar tech for now but if NTT has its way, nanofiber shirts will eventually be tracking the health of people everywhere. Just be sure that you keep your car’s speed a tad under 200 mph once you start rocking yours.

WATCH: This wearable airbag could save your life

Read more: http://mashable.com/2017/04/13/indy-500-indycar-tony-kanaan-wearable-tech/

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neophony · 2 years ago

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Neuphony EXG Synapse has comprehensive biopotential signal compatibility, covering ECG, EEG, EOG, and EMG, ensures a versatile solution for various physiological monitoring applications.

#neuroscience kit #diy neuroscience kit #hci kit #exg price #eeg diy #emg sensors #diy neuroscience #emg muscle sensor #wireless emg sensor

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rishabh3210blog · 6 years ago

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Global Fetal Monitoring Market Size, Industry Share, Growth & Forecast To 2025

Advances in fetal monitoring technology are one of the crucial factors driving the global fetal monitoring market. Several companies are working on the advances in fetal monitoring solutions, which include Koninklijke Philips N.V., General Electric Co., and PeriGen, Inc. For instance, Philips offers next-generation Avalon fetal monitoring solutions. This platform now comprises a spectrum of technical advances in transducer technology, monitoring, and measurement that enables mothers to move about during high-risk deliveries, during labor, and during routine and high-risk deliveries. In addition, the use of Smart Pulse technology enables to differentiate between fetal heart rate and maternal pulse without the requirement of additional sensors, such as ECG and SpO2. Other crucial innovations related to fetal monitoring solutions include-

Request a free sample of our report on Fetal Monitoring Market: https://www.omrglobal.com/request-sample/fetal-monitoring-market

Koninklijke Philips N.V. launched EPIQ Elite Ultrasound System-February 2019

Koninklijke Philips N.V.introduced EPIQ Elite ultrasound system. This system integrates the latest innovations in transducer innovation and augmented performance for improving the patient experience and clinical confidence. EPIQ Elite for Gynecology & Obstetrics offers realistic 3D scans and superior image quality to offer innovative fetal assessment at all phases of pregnancy. Based on the EPIQ Elite, the company’s new portfolio of systems and solutions integrates novel display technology, augmented processing power, cutting-edge software, and advanced transducers. The launch of this new platform is expected to leverage the company’s revenue from ultrasound systems and thereby will drive the global fetal monitoring market.

A full report of Global Fetal Monitoring Market is available at: https://www.omrglobal.com/industry-reports/fetal-monitoring-market

Nemo Healthcare launched the Nemo Fetal Monitoring System (NFMS)-November 2018

In November 2018, Nemo Healthcare launched the Nemo Fetal Monitoring System (NFMS), an advanced wearable device that can accurately monitor maternal and fetal heart rate and uterine activity, with a single measurement. The NFMS employs a multi-surface electrode patch with 6 electrodes. Uterine activity is derived from the EMG-signals when the uterine muscles contract and maternal and fetal heart rate are derived from the recorded ECG-signals. The system is intended to deliver accurate information for accurate and reliable early diagnosis and monitoring in an easy and safe way. It is non-invasive, and offers high-quality measurements, as well as is easy to use, wireless, and comfortable to wear.

GE Healthcare launched a new ultrasound imaging system named Versana Essential-January 2018

GE Healthcare introduced a new ultrasound imaging system named Versana Essential. It is designed to offer easy-to-use, advanced and perfect imaging quality. It can be used by OB/GYN to general practitioners and family practice physicians. This allows clinicians to offer the next level of care to their patients. The Versana Essential ultrasound machine is easy to learn, with online tools, including My Trainer and Scan Coach, supported by optional local ultrasound education that enables to perform ultrasound scans for obstetrics/ gynecology exams with more confidence and connect with your patients. This system comes with the powerful recognized imaging features of GE, including LOGIQ view, coded phase inversion harmonic imaging, Whizz, multiple line acquisition (MLA), color doppler, power doppler and pulse wave, Speckle Reduction Imaging (SRI), and CrossXBeam spatial compounding.

These new innovations in fetal monitoring systems can support to more accurately and reliably detect the fetal cardiac activity and movements. The adoption of these advanced fetal monitoring systems is expected to grow significantly owing to the rising incidences of preterm births and a significant rise in the number of multi-specialty hospitals, which in turn, will fuel the global fetal monitoring market.

Fetal Monitoring Market Segmentation

By Type

· External Fetal Monitoring

Electronic Fetal Monitoring

Internal Fetal Monitoring

By Application

Antepartum Fetal Monitoring

Intrapartum Fetal Monitoring

By End-User

Diagnostic Laboratories

Hospitals & Clinics

Others (Homecare and Research Institutes)

Fetal Monitoring Market – Segment by Region

North America

The US

Canada

Europe

Germany

France

Spain

Italy

Rest of Europe

Asia-Pacific

China

Japan

India

Rest of Asia-Pacific

Rest of the World

Visit here to know more about Global Fetal Monitoring MarketSize, Share, Trends.

About Orion Market Research

Orion Market Research (OMR) is an Indian market research and consulting company known for its crisp and concise reports. The company is equipped with an experienced team of analysts and consultants. OMR offers quality syndicated research reports, customized research reports, consulting and other research-based services.

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stocksnewsfeed · 6 years ago

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Sony Reveals New Line-up of Next-Generation Products, Solutions and Services at IBC 2019

SAN DIEGO, Sept. 13, 2019 /PRNewswire/ — At IBC in Amsterdam, Sony is unveiling its latest line-up of new products, solutions and services. These include: updated IP Live solutions, two IP extension adapters HDCE-TX30/HDCE-RX30, the FX9 4K E-mount camera with newly developed full-frame sensor for documentary shooting, an E-Mount Cinema lens FE C 16-35mm T3.1 G, as well as the PXW-Z750, an XDCAM® Shoulder Camcorder with 4K 2/3-type 3-chip CMOS sensor system with global shutter, and additional models to the DWX series Digital wireless microphone system.

Visitors to the Sony stand will be stunned by a 6K x 3K Crystal LED display system, showcasing breath-taking imagery with exceptional picture quality.

A key highlight will also be the newly-established Intelligent Media Services suite of services and micro-services. These support media companies in transforming traditional supply chains, unlocking more value from content for deeper audience engagement and helping them evolve into more agile organizations.

Pushing boundaries with IPBy working with broadcasters from across the world Sony has developed advanced IP Live Production solutions and has delivered more than 60 IP live studios and OB trucks to customers including Euro Media Group, DPG Media, NEP Australia and SIC Portugal. The updated IP Live line-up continues to drive efficiencies and increase ROI for customers by optimizing resource sharing and creating remote production environments.

HDCE-TX30/HDCE-RX30 – the two IP extension adapters transform current HDC series of SDI system cameras into IP-enabled cameras with SMPTE ST 2110 interface. Through their compact size, one third of the standard width, the IP extension adapters offer advanced IP Live remote production and resource sharing which create new efficient workflow patterns for existing HDC system cameras.

MKS-R4020/MKS-E1620 – two new remote-control panels that further strengthen the reliability, speed and accuracy of commands through Live Element Orchestrator.

PWSK-4509 – an optional interface board enabling SMPTE ST 2110 support for the PWS-4500 live production server.

Earlier this year, Sony and Nevion AS, a leading provider of virtualized media production solutions, entered into a strategic alliance. Together, Nevion and Sony aim to provide customers with the expertise and the products (both equipment and systems) needed to create tailored solutions for efficient and modern forward-looking live production operations. At IBC, together with United Broadcast, a subsidiary of Euro Media Group (EMG), and Century Link, Sony hosts an end-to-end IP Live total solution demo, connecting the Sony booth (A10 / Hall 13) with the Nevion booth (B79 / Hall 1) and an IP remote production studio in Hilversum. The demonstration will highlight the enormous potential that IP-powered remote productions and resource sharing can have for media organizations.

Sony has expanded its live production solutions line-up to include:

HKCU-REC55 – an option board for the Sony HDCU-5500, HDCU-3500 Camera Control Units (CCU) offering industry-first on-board recording capabilities. Realtime file transfer to NAS for post processing during recording as well as file transfer to a USB drive, ready to be removed and shared as soon as live production is over. In addition, simultaneous recording of 4K HDR and HD SDR strongly supports “SR Live for HDR” workflow. By using the PWA-RCT1 server control software, it is also possible to control multiple CCUs with the Sony PWS series live production server.

HDCU-5000 – a 19-inch 3U full rack size CCU compatible with most current HDC camera system including HDC-5500, HDC-3500, HDC-3100, HDC-2500, HDC-2400, HDC-1700, BPU-4000 and BPU-4500A. The CCU supports all necessary interfaces for 4K and HD production, including SMPTE ST2110 in 4K and HD, as well as maximum 8x 12G-SDI and 8x 3G-SDI output. High Frame Rate (HFR) over IP will be supported, as will the planned future option to provide the ability to record on-board to drive further efficiency in live production system.

HDC-5500 – system camera, launched at NAB, is also making its European debut at IBC.

RCP-3500 – a remote control panel for studio system cameras with a new LCD panel for improved visibility and the increased number of assignable switches and controls.

BVM-HX310 – The upcoming firmware version 1.1 of the flagship 4K HDR reference monitor of TRIMASTER HX will support the Monitor Auto White Adjustment function, which offers software-based color temperature calibration.

Offering greater creative freedom to content creators

Sony is introducing a number of new products and solutions aimed at content creators, including:

PXW-FX9 – XDCAM camera featuring a newly developed Exmor R 6K* full-frame sensor and Fast Hybrid Auto Focus system with the dedicated 561-point phase-detection AF sensor. The camera delivers an outstanding image that captures light and shade perfectly, thanks to its 15+ stops of latitude. Building upon the success of the PXW-FS7 and PXW-FS7M2, and inheriting its color science and the Dual Base ISO 800/4000 from the digital motion picture camera VENICE, the new camera offers greater creative freedom to capture stunning images and represents the ultimate tool of choice for documentaries, music videos, drama productions and event shooting. The FX9 is also compatible with the new UWP-D wireless microphone systems launched at NAB via Multi Interface Shoe™ (MI Shoe) with digital audio interface, incorporating the fast and easy channel setting NFC sync function in a compact lightweight design. *6K Oversampling, not capable of 6K recording

FE C 16-35mm T3.1 G lens – a new full-frame E-Mount Cinema lens offers high optical performance, reliable operability and intelligent shooting functions for professional video shooting.

DWX series Digital wireless microphone system – The third generation of the DWX digital wireless microphone system includes the DWR-S03D digital wireless receiver and the DWT-B30 bodypack transmitter, both planned to be available in December 2019. Sony has developed interface compatibility with UniSlot®** by utilizing DWA-SLAU1, D-sub 25pin adaptor for DWR-S03D, to offer a wideband digital audio solution for location sound recording for movies, dramas and documentaries. ** UniSlot® is a registered trademark of Ikegami Tsushinki Co., Ltd.

To further expand the operability in sound recording application, Sony collaborates with Sound Devices and AATON Digital respectively, leading companies in audio technology, for mutual support of applicable products. The firmware update of DWR-S03D receiver and their mixer-recorders enables the direct audio transmission between both devices, direct monitoring and control as well as scan and setting frequencies of Sony’s wireless microphone system from their mixer-recorder. The new firmware is planned to be available in Spring 2020 free of charge.

The digital motion picture camera VENICE, with its recently announced, customer driven version 5.0 firmware and version 4.0 now available in the market, will also be on display at IBC.

Getting ready for the future of news and live production

For those specializing in news and live productions, Sony is introducing the following new solution:

PXW-Z750 – a flagship XDCAM Shoulder Camcorder with 4K 2/3-type 3-chip CMOS Sensor system with global shutter technology for capturing clear and crisp images while negating artifacts such as flashband and rolling shutter distortion. PXW-Z750 offers greater sensitivity, less image noise and wider color gamut and can record in HD/4K and HDR, as well as support slow motion up to 120fps in HD. To improve workflow efficiency, the camcorder also has a built-in wireless module and is compatible with Sony XDCAM air cloud-based workflow service. In addition, PXW-Z750 can also be used with the latest DWX series digital wireless microphone system and offers enhanced usability including synchronized power on/off, control by menu settings or assignable buttons and audio information on the viewfinder by wireless audio solutions.

Artificial-Intelligence-based video analytics solution

REA-C1000 – an Edge Analytics Appliance, Sony’s first AI-based video analytics solution, continues to evolve with newly available functions enabled through its version 2.0 update such as chroma key-less CG overlay, which extracts presenters and overlays them onto multiple layered backgrounds without the need for a dedicated greenscreen or specialized training. REA-C1000 is showcased with latest generation of Pan Tilt Zoom Cameras, BRC-X400, SRG-X400 and SRG-X120.

“At Sony, everything we do is driven by our customers and our desire to help them realize their creative vision in the most efficient and streamlined way. Our aim is to provide them with real return on investment and help them make the most of their ideas through our products, services and solutions,” explained Theresa Alesso, pro division president, Sony Electronics.

Sony will be exhibiting at stand A10, Hall 13 at RAI Amsterdam from September 13-17. The Sony press conference is scheduled for 9:30am CEST on Friday, September 13, 2019 at the stand and will be streamed live.

For more information visit www.pro.sony/ibc.

About Sony Electronics Inc. Sony Electronics is a subsidiary of Sony Corporation of America and an affiliate of Sony Corporation (Japan), one of the most comprehensive entertainment companies in the world, with a portfolio that encompasses electronics, music, motion pictures, mobile, gaming and financial services. Headquartered in San Diego, California, Sony Electronics is a leader in electronics for the consumer and professional markets. Operations include research and development, engineering, sales, marketing, distribution and customer service. Sony Electronics creates products that innovate and inspire generations, such as the award-winning Alpha Interchangeable Lens Cameras and revolutionary high-resolution audio products. Sony is also a leading manufacturer of end-to-end solutions from 4K professional broadcast and A/V equipment to industry leading 4K Ultra HD TVs. Visit www.sony.com/news for more information.

SOURCE Sony Electronics Inc.

Related Links

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coolluminaryland-blog1 · 6 years ago

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Wireless Health Market to Observe Strong Development by 2023

The e-health monitoring system with wireless sensor network is used for patient telemonitoring and telemedicine. A 2012 article titled ‘In-home health monitoring to leap six-fold by 2017’ illustrated that Wireless remote monitoring devices will be used by more than 1.8 million people worldwide in the next four years. Of the billions of dollars spent on health care each year, 75% – 80% of it accountsfor patients with chronic illnesses such as diabetes, heart disease, asthma and Alzheimer’s disease. Over a decade, healthcare industry has taken a measured approach pertaining tointegrationof information technology (IT). Recent federal legislation and emerging trends, however, are changing the landscape and driving the need to accelerate the adoption of health IT in healthcare especially in medical devices.

Among wireless health products wearable medical devices is expected to be the fastest growing segment. Information delivered by modern wearable medical devices is easy to interpret and hence popularity is expected to increase rapidly within non-medical personnel. With these devices, peoplecan quickly modify their lifestyle to better improve their physical stature. Devices that measure temperature, heart rate and other parameters can be of paramount importance while determining physical fitness of a person.Over 65% of technologies are wrist held devices shaped like watches and the rest are wearable on other areas of the body such as arms, torso and waist. Along with the aesthetics, several other features for durability of the device are included such as waterproofing and weatherproofing. The latest in developments is telecommunication, wireless connectivity and improved user interface. The advent of smartphones has resulted in multi-fold increase of growth in applications that can now extend to storage and retrieval of history for the individual for long term mapping and improvement of fitness.

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Some of the major factors driving this market are the decreasing costs of electronics that has now made these devices available to middle and even low income groups over the world, and increased use of internet globally. According to the World Bank, number of internet users per 100 people increased from 15.8 in 2005 to 38.1 in 2013. The global wireless health market by products encompasses ECG monitors, insulin monitors, neuromonitors such as EEG and EMG devices.There are several devices which have in-build capability to diagnose, detect and send patient records to a centralized servers which can be easily accessed by healthcare providers. Advantages of wireless health devices encompasses patient comfort, accurate detection and analysis, access to stored patient data for a considerable longer period of time i.e. weekly or monthly. Recently Engineers at the University of Illinois at Urbana-Champaign and Northwestern University have demonstrated stick-on patches which can be used on a daily basis to monitor patient’s ECG. Additionally, the patient record can be easily accessed through a cell phone or computer wirelessly.

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Geographically the market can be studied for four geographical regions: North America, Europe, Asia Pacific and Rest of the Word. Currently, North America in terms of revenue accounts for the largest share owing to burgeoning population of cardiovascular diseases, diabetic patients. Moreover government initiatives such as the Affordable Care Act and favorable reimbursement scenario also promotes the sales and adoption of innovative wireless health monitoring and diagnostic products. Followed by the U.S., Europe holds the second leading position in the current scenario. Historically, the major EU countries have always been at the forefront of developing innovative healthcare technologies.In November 2013, Belgium-based research center Imec showcased its ideas for wearable sensor technologies for remote healthcare and personal health applications. The company introduced a body patch that integrates an ultra-low power electrocardiogram (ECG) chip and a Bluetooth low-energy radio. The company has also developed a prototype of a patient-friendly wireless EEG headset together with Holst Centre and Panasonic. Asia Pacific and Rest of the World market are among the fastest growing and largely untapped market. High cost of devices and lack of awareness about these devices are among the major restraint to the current adoption of the products in emerging market.

Some of the key players operating in this market encompasses Omron Corporation, GE Healthcare, Koninklijke Philips N.V., Polar Electro, Nihon Kohden, Siemens A.G., Mckesson Corporation,and Cerner Corporation.

About us:

Transparency Market Research (TMR) is a U.S.-based provider of syndicated research, customized research, and consulting services. TMR’s global and regional market intelligence coverage includes industries such as pharmaceutical, chemicals and materials, technology and media, food and beverages, and consumer goods, among others. Each TMR research report provides clients with a 360-degree view of the market with statistical forecasts, competitive landscape, detailed segmentation, key trends, and strategic recommendations.

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shellywrighttech · 3 years ago

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Smart Health Product Market 2022 Share, Trend, Segmentation and Forecast to 2028

Introduction:

Segmentation:

Market dynamics and factors:

Request Free Sample Report @ https://statisticalinsights.com/sample-request/11-Smart-Healthcare-Products

Regional analysis:

Geographically, Global health product market is segmented into North America, Europe, Asia Pacific, Middle East and Africa.

Key players:

Medtronic

Honeywell international inc.

Becton, Dickinson and company

AirStrip

Olympus Corporation

Flirtey

Flyzipline

Access Complete Report @ https://statisticalinsights.com/main-report/11-Smart-Health-Products-Market.php

Key industrial development:

Continue…

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#Tags:Smart Health Product Smart Health Product Industry Smart Health Product Market Smart Health Product Market Analysis Smart Health Produc

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marketresearchinsight-blog · 6 years ago

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Wearable Medical Device Market Is Estimated To Touch Land Mark Of $27.8 Billion By 2022: Grand View Research, Inc.

San Francisco, 09 Apr 2019 - The Global Wearable Medical Device Market is expected to reach USD 27.8 billion by 2022, according to a new report by Grand View Research, Inc. Rising prevalence of conditions such as obesity and hypertension, as a result of sedentary lifestyle is anticipated to boost the demand for wearable medical devices. Moreover, increasing health awareness is further expected to augment the demand for these devices.

Additionally, growing incidences of chronic conditions, such as diabetes, which require round-the-clock monitoring, are expected to increase the demand for wearable technology. Technological innovation is projected to be vital for growth of this industry over the forecast period. Smart watches, smart bands, and smart clothing are anticipated to be the key areas for development. Increasing penetration of smart cellular phones is expected to assist growth of this technology. However, patient privacy and security concerns along with complexity in engineering are expected to impede growth of the industry.

Access research report on Wearable Medical Device Market analysis: www.grandviewresearch.com/industry-analysis/wearable-medical-devices-market

Further key findings from the study suggest:

Diagnostic wearable medical devices held substantial share in 2014 owing to increasing usage in remote patient monitoring as well as home healthcare

Therapeutic wearable devices are anticipated to exhibit remunerative growth over the forecast period. Increasing penetration of products, such as insulin monitors, is assisting the growth of wearable equipment.

Diagnostic devices such as vital sign monitors are expected to witness lucrative growth over the forecast period. Rising incidences of chronic diseases are expected to boost the demand for this equipment.

Wearable medical devices have applications in sports & fitness monitoring, home healthcare, and remote patient monitoring. Home healthcare held significant shares of around 50.0% in 2014. Simplified usage of this equipment along with ability to synchronize with cellular phones as well as tablet devices assisted the growth of this segment.

On the contrary, remote patient monitoring is projected to exhibit growth rate of over 25.00% in the next seven years. Increasing geriatric population base coupled with demand for continuous monitoring is expected to fuel the growth.

Strap/clip/bracelet or watches held substantial shares of around 40.0% in 2014, and is expected to grow at a lucrative rate over the forecast period. Simplified engineering, aesthetically appealing products, and synchronization with mobile application are anticipated to drive this segment’s growth.

North America dominated the overall market with approximately 40.0% of shares. This can be attributed to increasing per capita income as well as rising healthcare spending, and advanced healthcare infrastructure and presence of OEM in this region.

Asia Pacific is projected to grow with a rapid rate of around 32.0% over the forecast period. Economic development coupled with improving healthcare systems is expected to help the industry grow in this region.

Key companies of the wearable medical devices industry include Fitbit Inc., Garmin, Vital Connect, Omron Corp., Sotera Wireless, Jawbone, Pebble Technology Corp., Basis Science, Inc., Withings, Intelesens Ltd., Covidien Plc, LifeWatch AG, Polar Electro, Philips Electronics, and Everist Genomics

Read Our Blog: http://www.grandviewresearch.com/blogs/healthcare

Grand View Research has segmented the global Wearable Medical Device Market on the basis of products and region:

Global Wearable Medical Devices Product Outlook (USD million), 2012–2022

Diagnostic devices

Vital sign monitors

Heart rate monitors

Activity monitors

Electrocardiographs

Pulse oximeters

Spirometers

Blood pressure monitors

Other devices

Sleep monitoring devices

Sleep trackers

Wrist actigraphs

Polysomnographs

Other devices

Electrocardiographs Fetal & Obstetric Devices

Neuromonitoring devices

Electroencephalographs (EEG)

Electromyographs (EMG)

Other devices

Therapeutic devices

Pain management device

Neurostimulation device

Other devices

Insulin monitoring device

Insulin pumps

Other devices

Rehabilitation device

Accelerometers

Sensing devices

Ultrasound platforms

Others

Respiratory therapy device

Ventilators

PAP

Portable oxygen concentrators

Other devices

Global Wearable Medical Devices Application Outlook (USD million), 2012–2022

Sports & Faintness

Remote Patient Monitoring

Home healthcare

Global Wearable Medical Devices Site Outlook (USD million), 2012–2022

Handheld

Headband

Strap, clip, bracelet and watches

Shoe sensors

Others

Wearable Medical Devices Region Outlook (USD million), 2012–2020

North America

US.

Mexico

Europe

Germany

France

Asia Pacific

Japan

China

India

Latin America

Brazil

Mexico

MEA

South Africa

Saudi Arabia

About Grand View Research

Grand View Research, Inc. is a U.S. based market research and consulting company, registered in the State of California and headquartered in San Francisco. The company provides syndicated research reports, customized research reports, and consulting services. To help clients make informed business decisions, we offer market intelligence studies ensuring relevant and fact-based research across a range of industries, from technology to chemicals, materials and healthcare.

For More Information: www.grandviewresearch.com

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panjapop · 7 years ago

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The Metaplasm

The Metaplasm is a mixed reality piece that consists of a computational leather prosthetic and an augmented computer vision app. The shoulder garment computes the wearer's movement data to the app which mixes a phantom augmentation of floating images with their live camera feed.

I was inspired by a section in Wendy Chun’s Updating to Remain the Same that talked about phone users feeling their mobile phones vibrate without a phone call being attempted. This phenomenon was equated with phantom limb syndrome where amputees often have strong sensations of their missing limb in random circumstances and without explanation. I was curious about how we could use technology to illuminate subconscious internal thought patterns, an altered state of some sort with the potential to unlock areas within our brain.

Since the success of the smart phone and it's suite of social apps, wearable tech gadgets have started to bleed into our daily lives in their drive to help us perform better. But they are also subtly changing our behaviours, turning us into performance junkies and driving us to loose touch with our previous internal selves. I was interested in exploring what our internal selves might look like? So I began to research different artists that worked with prosthetics to hack their bodies in different ways to create different sensations.

The australian cypriot performance artist Stelarc uses his body as a rich interaction platform, visibly hacking it with electronics to blur the boundaries between man and machine. In his Third Hand project a cyborg like robotic arm attachment is controlled by the EMG signals from other parts of the performer's body. Rebecca Horn’s Body sculptures and extensions are shaped by imagining the body as a machine. In her Extensions series Horn’s armatures remind of 19th century orthopaedic prosthetics supporting an injured body. Her armatures are redirecting the body's purpose, turning it into an instrument and often inducing a feeling of torture.

Ling Tan’s Reality Mediators are wearable prosthetics that cause unpleasant sensations when the wearer’s brain activity or muscle movement are low. Her project is a direct comment on to the effect current wearables have on our perception of the world around us and the way these products alter our daily behaviours.

I decided on designing a shoulder prosthetic that communicates with a computer vision app to allow it's wearer play with an augmented trail of images. It was important to me to present the experience as a clash of two worlds. The old world was represented by the prosthetic which took great inspiration in victorian prosthetics. I researched the look of these at the Wellcome Collection. But I also wanted the prosthetic to look really attractive and contemporary. Here

I took visual inspiration from Olga Noronha's Ortho Prosthetics series. Rather then being a tool to help the physical body function better the prosthetic had the purpose to unlock and help navigate an internal monologue of thought images represented by the projection. The images featured stuff in our head that alludes from online shopping activity to stuff we see out and about. The camera feed holds the wearer as the centre point surrounded by a crude collection of stuff.

Reading Donna Harraway's Companion Species I came across a great section where she talks about metaplasms. She explains "I use metaplasm to mean the remodelling of dog and human flesh, remolding the codes of life, in the history of companien-species relating." Whilst Haraway explores the blurred boundaries in relationships between dogs and humans, this descriptor felt to be a very fitting title for an experience that aims to illuminate internal phantoms, that accumulate inside of us and we have no idea how to control.

I began dividing my project into two parts: The physical prosthetic and the augmented computer vision app. Having played with the latter in my last project I decided to concentrate on the physical aspects first. Here I decided to use the Arduino compatible Adafruit Flora board with the LSM303 Accelerometer Compass Sensor. I also initially thought I would make the whole experience wireless and ordered the Bluefruit LE Bluetooth Module and the rechargeable LiPo battery pack. It was important to get the components onto my physical body asap to start testing where they should sit for their maximum efficiency. I layed them out on some cheap felt and sewed them on with conductive thread according to the great help section on the Adafruit website. Despite getting the bluetooth communication to work immediately I struggled to add on the accelerometer too. The connections seemed temperamental so I decided to remove the bluetooth simplify the cross component communication. Later I got some advice that made me rethink the use of bluetooth in the church and decided that a 3m long micro usb would actually suit my aesthetic whilst making the experience more reliable. I also at this point decided to solder silicon wires onto the board instead of the less conductive thread. Now my connections were very stable and I got clear differences when moving my arm. I used the accelsensor file that came with the LSM 303 library and tested my movements in the Serial Monitor. I integrated last values and current values to let the app create a different value for the acceleration by subtracting the last value from the current value. I found it hard though to separate the x y z values from each other and making these be linked to understandable directions when sitting on the lower arm. To save time I decided to add all the difference values together with the abs function to create a single agitation value that was then communicated to the app. I tested the communication between the electronics and openframeworks with ofSerial to make sure the app would receive the values ok before parking the tech development and concentrate on the design of the prosthetic.

From doing my initial tests with the electronics I knew that I needed the Flora board on the shoulder and the accelerometer lower down on the arm. I wanted to make the prosthetic as adjustable as possible accommodating as many different body sizes as possible. I started by using thick wall paper lining paper to cut my first pattern fitting it to a size 8 dressmaker dummy that I have at home. I created loads of adjustable straps to adapt the distances between neck, shoulder and lower arm. From there I moved onto cutting it out from dressmakers Calico and sewing it together to make my next prototype. In the meantime I researched a leather workshop that sold amazing fittings such as brass Sam Browns and brass eyelids to pin the leather to the bottom layer of calico and make adjustable fittings. There I also found cheap leather off cuts to make my next prototype. Being fairly happy with my paper pattern it was time to digitise it by scanning it on a flat bed scanner and then to trace and tidy the lines in illustrator. At this point I also created the exact openings for the electronics. I wanted to create little pockets that would allow me to whip them out quickly to replace them in case they got broken. I placed the Flora board and the accelerometer on little calico pieces sewing the connections down so they became more protected. I also designed little leather flaps to cover and further protect the areas where the wires were soldered onto the board. Now that I had a digital pattern I was able to laser cut the leather as a last test before my final prototype. The laser cutter charred the leather at the edges producing an overwhelming bbq charcoal smell that I didn’t want in my final piece. I assembled the prototype to see whether I needed to make any final changes to the digital pattern. Now I was able to instruct a leather worker to cut out my final piece from the leather following my printed out pattern and referencing the assembled prototype whilst doing so.

It was time to move on with creating the augmented phantom. For this I used Vanderlin's box2d addon to add real physics behaviour to the floating augmented images. I used the 'joint' example that consisted of several joints and lines and a anchor. I combined this file with the openCV haarfinder example so that the app once detects a face could hang this joint example onto the user's shoulder. I created a separate class for the box2D trail and fed in my movement data by creating a variable to affect the trail. I created black outline squares and little white circles to mirror the aestetic of the computervision app and tested my movements. At this point I brought in some random images fed them into a vector to draw them into the outline squares on the same x/y values. Playing around with it I decided that it would be nice if the images would randomly reload adding an element of surprise and control for the user. I build an algorithm that would reload the vector when the user's agitation data accelerated the trail to the top of the screen. This worked pretty well and by this point it was time to test it in location.

I knew my installation set-up was going to be challenging as I had to project on a full height wall whilst meeting the lighting needs of a computer vision app. I was positioned by the edge to the big space of the church, the beginning of an area that was meant to be semi dark whilst receiving all the light from the big space. The BenQ short throw projector was surprisingly powerful to give a pretty crisp and high lumen projection in a semi dark space. I fit a PS3 Eyegrabber camera on the wall of the projection and a spot light further up shining at the user and in direction of the projector. I fitted a hanging sheet over the wall thereby hiding the camera except for a little hole where the lense could fit through. I hung my shoulder prosthetic from the ceiling with a thin bungee elastic allowing it to be pulled down to different heights without any accidents.

Now I was ready to test the interaction space and positions of the lamp by bringing in players of different heights all throughout the day for several days. Despite everyone's lighting requirements in the big open space getting nailed down and fitted with my own I found the experience quite frustrating as the natural daylight would change throughout the day and I could do anything about that. I settled with the shortcomings and carried on refining the app. For this I decided to produce 50 images representing daily life and modern world meme’s. These I loaded into the app to create a good level of variation to delight the user. Then I created a screen shot facility to record interactions ie take a screenshot every time the app sees a face and every 20 seconds of interaction, so I wouldn’t get too many. I also decided to design a fixing hook for my bungee so the user could take it off the elastic and wouldn’t get tangled up in it whilst moving about.

Testing the prosthesis on well over 100 users over the course of 3 days and observing each person interact with it convinced me to build the experience wireless next time. It was a real joy to witness the different interaction behaviours users came up with. Some wanted to dance, some were play acting, some wanted to use leap motion behaviours to grab the images and some were just terrified. Overseeing this process and closely engaging with over 40 users on opening night alone was really fascinating, despite also being very tiring. I temporarily considered hiring someone but wouldn't have had the time to train them to say the right things nor ask the right questions. It was great to so closely engage with people, dressing the different body shapes and constantly learning about what could be made different. A lot of users obviously suggested a more personalised experience ie. their own images. Talking through with them what this would mean though in terms of a privacy opt in and an open projection of their online activity they quickly understood that the player take up would be low and the experience would most likely also look very different. I hope my conceptual approach to this matter gave them enough food for thought to imagine what images might be floating in their heads though. But I also came across some interesting potential use cases from my audience. One worked with paraplegic kids and suggested the experience to have potential as a training app to a reinvigorate a lazy arm. I had a similar comment from an Alexander technique teacher. I'm interested in exploring this further and looking into integrating sensory feedback or linking the prosthetic to another device.

Overall I’m really happy with the prosthetic. It fitted most body sizes with a few exceptions. I would like to make a few adaptations but am otherwise very happy with the look and feel of it. If I had had more time I would have integrated a little vibrator within the shoulder to add sensory feedback when the user reloaded the vector or pulled in a particular image. I would definitely decide on a more controlled lighting set-up with a bigger interaction space, potentially even a huge monitor and a wireless prosthetic. Despite these constraints I was surprised how many users enjoyed playing with the images ignoring the obvious glitchiness of the facial tracking.

#metaplasm #computervision #flora #openframeworks #physicalcomputing #computationalart

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batstrangecloudcollection-blog · 7 years ago

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Patient Monitoring Device/System/Equipment Market worth $25.31 Billion by 2023

The report "Patient Monitoring Device/System/Equipment Market by Product (EEG, EMG, MEG, TCD, Peak Flow Meter, Pulse Oximeter, Fetal Monitoring, Temperature Monitoring Devices, MCOT, ECG, Hemodynamic Monitoring System), End User (Home, Hospital) - Global Forecast to 2023", The patient monitoring devices market is projected to reach USD 25.31 Billion by 2023 from USD 19.14 Billion in 2018, at a CAGR of 5.7%. Factors such as the easy availability of wireless monitoring devices and the rising incidence of lifestyle and chronic diseases are expected to drive market growth during the forecast period. The growing demand for patient monitoring devices in non-hospital settings is also expected to provide a range of growth opportunities for players in the market. On the other hand, the risks associated with invasive monitoring devices are expected to challenge market growth to a certain extent in the coming years.

The ECG segment is expected to account for the largest share of the cardiac monitoring devices market in 2018

Request For Brochure : https://www.marketsandmarkets.com/pdfdownload.asp?id=678

By product, the cardiac monitoring devices market is classified into ECG devices, IRLs, event monitors, MCT monitors, and smart wearable ECG monitors. In 2018, the ECG devices segment is expected to account for the largest share of the market. The large share of this segment can primarily be attributed to the increasing incidence of cardiovascular diseases, the wide application of ECG devices in CVD management, the development of technologically advanced devices, and government initiatives.

The cerebral oximeter segment is expected to grow at the highest CAGR in neuromonitoring devices market during the forecast period

By product, the neuromonitoring devices market is divided into EEG machines, cerebral oximeters, EMG machines, ICP monitors, MEG machines, and TCD machines. In 2018, the cerebral oximeters segment is expected to grow at the highest CAGR during the forecast period. Cerebral oximeters offer real-time data to physicians through a noninvasive procedure. This is a major factor driving the growth of this market. The real-time data obtained is useful to make emergency care decisions and observe the effects of interventions.

The pulse oximeters segment is expected to account for the largest share of the respiratory monitoring devices market in 2018

By product, the respiratory monitoring devices market includes pulse oximeters, spirometers, capnographs, and peak flow meters. In 2018, the ECG devices segment is expected to account for the largest share of the market. The development of innovative products such as fingertip pulse oximeters, pulse oximeter sensors, and Bluetooth-enabled pulse oximeters—and their growing uptake are the key factors driving the growth of the pulse oximeters market.

For More Info Visit : https://www.marketsandmarkets.com/PressReleases/patient-monitoring-devices.asp

#Patient Monitoring Device/System/Equipment Market

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research-analyst-posts-blog · 8 years ago

Text

Wearable Medical Device Market Qualitative Analysis by Industry Overview, Trends, Growth Prospects And Key Market Opportunities 2012-2022

Global Wearable Medical Device Market is expected to reach USD 27.8 billion by 2022, according to a new report by Grand View Research, Inc. Rising prevalence of conditions such as obesity and hypertension, as a result of sedentary lifestyle is anticipated to boost the demand for wearable medical devices. Moreover, increasing health awareness is further expected to augment the demand for these devices.

Full Research Report on Global Wearable Medical Device Market Analysis: http://www.grandviewresearch.com/industry-analysis/wearable-medical-devices-market

Further key findings from the study suggest:

Diagnostic wearable medical devices held substantial share in 2014 owing to increasing usage in remote patient monitoring as well as home healthcare

View more reports of this category by Grand View Research at: http://www.grandviewresearch.com/industry/medical-devices

Grand View Research has segmented the Global Wearable Medical Device Market on the basis of products and region:

Global Wearable Medical Devices Product Outlook (USD million), 2012 - 2022

Diagnostic devices

· Vital sign monitors

§ Heart rate monitors

§ Activity monitors

§ Electrocardiographs

§ Pulse oximeters

§ Spirometers

§ Blood pressure monitors

§ Other devices

· Sleep monitoring devices

§ Sleep trackers

§ Wrist actigraphs

§ Polysomnographs

§ Other devices

· Electrocardiographs Fetal & Obstetric Devices

· Neuromonitoring devices

§ Electroencephalographs (EEG)

§ Electromyographs (EMG)

§ Other devices

· Therapeutic devices

· Pain management device

§ Neurostimulation device

§ Other devices

· Insulin monitoring device

§ Insulin pumps

§ Other devices

· Rehabilitation device

§ Accelerometers

§ Sensing devices

§ Ultrasound platforms

§ Others

· Respiratory therapy device

§ Ventilators

§ PAP

§ Portable oxygen concentrators

§ Other devices

Global Wearable Medical Devices Application Outlook (USD million), 2012 - 2022

Sports & Faintness

Remote Patient Monitoring

Home healthcare

Global Wearable Medical Devices Site Outlook (USD million), 2012 - 2022

Handheld

Headband

Strap, clip, bracelet and watches

Shoe sensors

Others

Wearable Medical Devices Region Outlook (USD million), 2012 – 2020

U.S.

Mexico

Germany

France

Japan

China

India

Brazil

Mexico

South Africa

Saudi Arabia

View Press Release of this research report by Grand View Research: http://www.grandviewresearch.com/press-release/global-wearable-medical-device-market

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