Smart ring
A smart ring is a compact, finger-worn wearable electronic device that integrates sensors, microprocessors, and wireless connectivity—typically Bluetooth—to monitor health and fitness metrics such as heart rate, blood oxygen levels, sleep quality, body temperature, and physical activity, while also enabling features like smart notifications, contactless payments via NFC, and gesture controls for connected devices.[1][2][3] The development of smart rings traces back to the early 2000s, when initial prototypes focused on NFC-enabled access control for secure entry to buildings, vehicles, and electronics, marking the first practical applications of ring-form wearables.[4] The category evolved significantly in the mid-2010s with an emphasis on health tracking; Oura Health, founded in 2013 in Oulu, Finland, launched the first Oura Ring generation in 2016 via a successful Kickstarter campaign that raised approximately $652,000 from over 2,300 backers, introducing advanced sleep and recovery monitoring validated by studies like one from Stanford in 2017.[5] Subsequent milestones included the Oura Ring Gen 2 in 2018, Gen 3 in 2021 with women's health features, and Gen 4 in 2024 featuring enhanced "Smart Sensing" for more accurate data collection.[5] Other early entrants, such as the Motiv Ring in 2016 and NFC Ring for payments, laid groundwork for multifunctional designs, but health-focused models dominated by the 2020s.[2] As of 2025, smart rings have become a burgeoning segment of the wearable technology market, valued at $349.1 million in 2024 and forecasted to reach $1.6 billion by 2032 with a compound annual growth rate (CAGR) of 21.3%, driven by demand for discreet, subscription-based wellness tools. In October 2025, Oura Health raised $900 million in funding led by Fidelity, highlighting strong investor interest.[6][7] Leading products include the Oura Ring 4 ($349–$499), praised for its comprehensive sleep, stress, and activity tracking with a required $5.99/month membership; the Samsung Galaxy Ring ($399), optimized for Android users with no subscription and features like energy score assessments; and the Ultrahuman Ring Air ($349), noted for subscription-free fitness insights including metabolic recovery and movement indexing.[8][9][10] These devices sync data to companion smartphone apps for personalized insights, though battery life typically ranges from 4–7 days, and sizing accuracy remains crucial for optimal sensor performance.[1][11] Market expansion involves partnerships with carriers like AT&T and Verizon, alongside research into advanced applications such as extended reality interfaces.[12]Definition and overview
What is a smart ring
A smart ring is a compact, finger-worn wearable electronic device that integrates sensors, processors, and wireless connectivity to discreetly track user data and enable smart functions.[2][13] Unlike traditional jewelry, which primarily serves aesthetic or symbolic purposes, a smart ring emphasizes computational capabilities to monitor biometrics and interact with other devices.[13][2] The primary functions of a smart ring include continuous biometric monitoring, such as heart rate and sleep patterns, along with gesture controls for device interaction and seamless integration with smartphones for data syncing and analysis.[14][15] These features allow users to gain insights into their health and wellness without the bulk of larger wearables like smartwatches.[16] In terms of form factor, smart rings are typically constructed from durable materials like titanium for the exterior and hypoallergenic epoxy resin for the interior lining, available in US sizes ranging from 4 to 13 to accommodate various finger circumferences.[17][18][19] They often feature IP68 water resistance ratings, enabling 24/7 wear during activities like showering or swimming without removal.[20][18]Advantages over other wearables
Smart rings offer a distinct advantage in terms of wearability and comfort compared to bulkier wrist-based wearables like smartwatches and fitness bands. Typically weighing between 2 and 5 grams depending on size and model, smart rings are significantly lighter than smartwatches, which often range from 30 to 50 grams, allowing for unobtrusive all-day and overnight use without the bulk or strap irritation associated with wrist devices.[18][21][22] This featherweight design enables users to forget they're wearing the device, promoting consistent tracking during activities where wrist wearables might feel cumbersome or get in the way.[19] Another key benefit is their superior battery efficiency, stemming from the absence of a display and reliance on passive sensors rather than active screens or frequent syncing. Many smart rings provide up to 7 days of battery life on a single charge, far outlasting the typical 1-2 days (or less) offered by smartwatches, which drain power through always-on displays and notifications.[23][11][24] This extended runtime minimizes downtime for charging, ensuring uninterrupted health monitoring, particularly during sleep when wrist devices are often removed.[25] In terms of data accuracy for specific metrics, smart rings excel in sleep and recovery tracking due to their finger placement, which positions sensors closer to peripheral arteries for more precise pulse oximetry and motion detection compared to wrist-based alternatives. Studies have shown that devices like the Oura Ring achieve acceptable clinical-grade accuracy for blood oxygen saturation (SpO2) under non-motion conditions, with strong agreement to polysomnography for metrics like the oxygen desaturation index during sleep.[26][27] This positioning reduces motion artifacts common in wrist trackers, leading to reliable insights into sleep stages and recovery without the interference of arm movements.[28][29] Finally, the screenless design of smart rings enhances privacy and social subtlety by eliminating visible notifications or displays that could expose personal data or cause distractions in professional or social settings. Without a screen, these devices avoid the "social awkwardness" of glancing at a wrist device repeatedly, reducing the risk of unintended data visibility to others and allowing for discreet, background health monitoring.[30][31][32] This passive operation also limits exposure to potential hacking vectors associated with interactive screens on other wearables.[33]History
Early concepts and prototypes
The early concepts of smart rings originated in the early 2000s, as researchers in academic and tech labs explored embedding wireless technologies into compact jewelry forms to enable seamless interaction with devices. These conceptual designs primarily integrated RFID for access control applications, such as hands-free door unlocking or identity verification, demonstrating the feasibility of miniaturizing RFID chips within ring structures to replace traditional keys or badges. Prototypes from this era, often developed in design workshops and engineering labs, focused on proving the practicality of RFID in wearable formats while maintaining aesthetic appeal. A key milestone occurred in 2005 with the introduction of the first Bluetooth-enabled smart ring, which allowed users to control mobile phones hands-free via simple gestures or inputs, paving the way for gesture-based interactions in wearables. This prototype emphasized basic connectivity but remained experimental due to emerging Bluetooth standards.[4] In 2013, British inventor John McLear developed the NFC Ring, a groundbreaking prototype from McLear Limited that shifted focus toward payment capabilities. This ring incorporated near-field communication (NFC) technology to facilitate contactless transactions, device pairing, and data sharing at NFC-enabled terminals, without incorporating health or fitness tracking features. Launched through a Kickstarter campaign, it highlighted the potential for smart rings in secure, everyday financial interactions and garnered attention for its passive, battery-free operation.[34][35] Development of these early prototypes was constrained by significant technical hurdles. Miniaturization posed a major challenge, as fitting sensors, chips, and antennas into a ring's limited space often resulted in uncomfortable or oversized designs. Battery life typically fell short of 24 hours, limiting continuous use and requiring frequent recharging that undermined portability. Production costs for prototypes exceeded $200 per unit, driven by custom components and low-scale manufacturing, which impeded broader testing and commercialization efforts.[36]Commercialization and key milestones
The commercialization of smart rings began with the founding of Oura Health in 2013 in Oulu, Finland, where the company initially concentrated on developing a wearable device centered on sleep tracking to provide users with detailed insights into rest and recovery.[37] A pivotal milestone occurred in 2015 when Oura launched its first-generation ring through a successful Kickstarter campaign, raising approximately $650,000 from over 2,000 backers, which enabled the production and market entry of the Gen 1 Oura Ring as an early health monitoring wearable.[38][39] Between 2017 and 2020, the Motiv Ring emerged as a key entrant in the activity-focused segment, launching in 2017 with features for tracking steps, heart rate, and sleep, before being acquired by digital identity firm Proxy in 2020, shifting its emphasis toward enterprise biometrics rather than consumer fitness.[40][41] In 2023, Ultrahuman introduced the Ring Air, a subscription-free smart ring designed for comprehensive health tracking without ongoing fees, marking a significant push toward accessible, no-cost data access in the category.[42][43] Concurrently, Samsung teased the Galaxy Ring at its 2024 Unpacked event, building anticipation for its 2024 launch as the company's first smart ring integrating Galaxy AI for advanced health insights like sleep analysis and energy scores.[44][45] From 2023 to 2024, McLear advanced payment capabilities through its RingPay program, launching RingPay 2 in June 2023 with new color variants and partnerships including Visa and Thales announced in November 2023 for contactless transactions, though the prepaid service concluded operations in October 2024 due to rising maintenance complexities.[46][47][48] The Oura Ring 4 debuted in October 2024, featuring enhanced sensor accuracy and AI-driven features, including updates to its Readiness Score in early 2025 that incorporated menstrual cycle data for more personalized recovery assessments.[49][50] By 2025, the global smart ring market had expanded to a valuation of approximately $417 million, reflecting rapid adoption driven by health-focused innovations and broader availability.[51]Design and technology
Hardware components
Smart rings are constructed from lightweight, durable materials to ensure comfort during extended wear. Common materials include titanium alloys, valued for their strength, corrosion resistance, and hypoallergenic properties, which minimize skin irritation. For instance, the Oura Ring 4 utilizes fully titanium construction, contributing to its robustness while maintaining a sleek profile. Some models incorporate hypoallergenic resins or ceramic coatings for added skin compatibility and aesthetic variety, as seen in the Oura Ring 4 Ceramic edition. These materials typically result in device weights ranging from 2 to 8 grams, depending on size and finish, allowing for unobtrusive all-day use without compromising structural integrity.[22][52][53] The sensor suite in smart rings enables passive data collection from the finger, leveraging its vascular proximity for accurate physiological readings. Photoplethysmography (PPG) sensors, often employing red and infrared LEDs paired with photodiodes, measure blood volume changes to detect heart rate and blood oxygen saturation (SpO2). A 3-axis accelerometer captures motion and orientation data, facilitating gesture recognition and activity tracking through acceleration vectors along x, y, and z axes. Temperature sensors monitor skin surface variations, providing indicators for physiological states like recovery or environmental adaptation. These components are recessed into the inner band to maintain a smooth exterior while ensuring reliable contact with the skin.[22][54][55] Power systems in smart rings prioritize efficiency to support compact form factors. Lithium-polymer batteries, with capacities typically between 10 and 25 mAh, power the sensors and minimal onboard processing, offering 4 to 8 days of usage on a single charge under normal conditions. Inductive charging via a dedicated dock replenishes the battery in 20 to 120 minutes, eliminating exposed ports and enhancing water resistance. For example, the Samsung Galaxy Ring's 18-23.5 mAh battery sustains up to 7 days of operation.[53][22] Sizing and environmental durability are critical for practical adoption. Manufacturers provide modular sizing kits covering US sizes 4 to 13 (or up to 15 in some cases), allowing users to determine the optimal fit via trial rings before purchase. Ingress protection ratings of IP67 or IP68 ensure resistance to dust and water immersion up to 100 meters for 30 minutes or more, suitable for swimming or showering. The Oura Ring 4, for instance, achieves 100m water resistance with its titanium build. Basic Bluetooth connectivity modules, often version 5.0 or higher, integrate seamlessly with these hardware elements for data offloading.[22][56][53]Software and connectivity
Smart rings typically operate using custom lightweight firmware rather than full-fledged operating systems, enabling efficient power management and sensor integration on resource-constrained hardware. For instance, the Oura Ring employs proprietary firmware that supports over-the-air updates to enhance functionality, such as power optimizations in version 2.6.2 released in September 2025.[57] These firmware systems handle core tasks like sensor data acquisition and basic processing, while companion mobile applications—built for iOS 16 or higher and Android 9 or higher—provide user interfaces for data visualization, trend analysis, and personalized insights.[58][59][60] Connectivity in smart rings prioritizes low-power wireless protocols to maintain extended battery life without compromising data transfer reliability. Bluetooth Low Energy (BLE), often version 5.0 or later, serves as the primary standard for pairing with smartphones, allowing seamless synchronization of health metrics to apps like Samsung Health or the Oura App.[61][22] Some models incorporate Near Field Communication (NFC) for authentication and access control, though contactless payments are not supported in leading health-focused smart rings as of 2025.[62] Data processing in smart rings balances on-device computation with cloud-based analytics to deliver timely insights while minimizing latency and bandwidth use. Edge computing enables local AI algorithms to generate basic metrics, such as heart rate variability (HRV), which is computed as the standard deviation of normal-to-normal (NN) intervals from photoplethysmography signals, providing immediate feedback on autonomic nervous system balance without constant phone connectivity.[63][64] More complex trend analysis, including longitudinal patterns in sleep and activity, occurs via cloud servers, leveraging machine learning models for personalized recommendations after data is securely uploaded.[65] Security protocols in smart rings emphasize protection of sensitive biometric data through robust encryption and compliance standards. End-to-end encryption secures transmissions from the device to cloud services, using protocols like TLS 1.2 or higher to prevent interception during Bluetooth or Wi-Fi syncs, as implemented in the Oura ecosystem.[66][67] Many manufacturers adopt subscription models to gate advanced features, such as detailed analytics and AI-driven insights; for example, Oura Membership costs $5.99 per month after an initial trial, unlocking full app capabilities while ensuring ongoing security updates.[68]Features
Health and fitness monitoring
Smart rings primarily utilize photoplethysmography (PPG) sensors and accelerometers to track essential health and fitness metrics, enabling continuous, unobtrusive monitoring without the bulk of wrist-based devices. Heart rate is measured in beats per minute (bpm) through optical sensors that detect blood volume changes in the finger, providing real-time data during rest and activity. Activity levels, including steps and calorie expenditure, are derived from motion data captured by integrated accelerometers, which analyze movement patterns to estimate daily energy output. Sleep stages—such as REM, deep, and light sleep—are determined by combining PPG for heart rate variability (HRV) and accelerometer inputs for body position and restlessness, offering users a breakdown of nightly rest quality.[69] Advanced insights extend beyond basic tracking to include composite scores like readiness, which integrates HRV, previous night's restfulness, and recent activity to gauge daily recovery and performance potential on a 0-100 scale. Stress monitoring relies on variations in skin temperature and HRV, where elevated stress correlates with reduced HRV and temperature deviations from baseline, helping users identify periods of physiological strain. For women's health, basal body temperature tracking detects subtle shifts (approximately 0.3-0.7°C) to predict menstrual cycles and fertile windows, often integrated with algorithms for ovulation detection. While useful for cycle tracking, these features are not reliable for contraception and should not replace medical birth control methods, as fertility awareness effectiveness varies from 77-98% with perfect use. These features draw on hardware like temperature sensors referenced in smart ring designs, allowing passive data collection throughout the day.[70][71][72] Accuracy studies validate these capabilities against clinical gold standards, with the Oura Ring showing no significant difference from polysomnography (PSG) for total sleep time, wake, light sleep, deep sleep, and REM stages in controlled evaluations. A 2024 validation study for Oura Ring Gen4 reported 79% overall agreement in four-stage sleep classification, with 79.5% sensitivity for deep sleep detection. However, a 2025 independent study found 53% overall sleep staging accuracy for Oura versus PSG (kappa=0.31), with challenges in distinguishing wake (46% sensitivity) from light sleep, though stronger for deep sleep. Heart rate measurements exhibit a mean bias of -0.4 bpm compared to electrocardiography (ECG), indicating high reliability during nocturnal periods. Limitations arise during intense workouts or dynamic activities, where motion artifacts can affect accelerometer-based step counts, with some studies showing overestimation by 10-20% compared to reference devices; the absence of built-in GPS requires phone pairing for precise distance and location tracking in GPS-dependent activities like running. Ongoing research emphasizes the need for device-specific validation in diverse populations.[29][28][69][73][74] In practice, users receive daily reports synthesizing these metrics into actionable insights, such as recommending rest after low readiness scores or adjusting exercise based on elevated stress indicators, thereby guiding decisions on recovery and training intensity. For instance, cycle tracking data can inform lifestyle adjustments during menstrual phases, enhancing overall wellness management through personalized feedback loops. These applications underscore the role of smart rings in promoting proactive health behaviors.[75]Security and payments
Smart rings incorporate biometric security features in select premium models to enable secure authentication without relying on traditional passwords or keys. For instance, the Token Ring utilizes built-in biometric sensors for multifactor authentication (MFA), verifying the user's identity through physiological traits to prevent phishing and ransomware attacks by ensuring the ring is worn by the authorized individual during use.[76] Similarly, Samsung has patented a fingerprint authentication system for its Galaxy Ring, employing ultrasonic sensors to scan and match finger patterns for device unlocking.[77] Research prototypes, such as the ScanRing, explore hybrid authentication using a distance sensor for facial structure capture and an inertial measurement unit (IMU) for motion patterns, allowing gesture-based verification in ring form factors for enhanced security in applications like payments and access.[78] These systems often pair with Bluetooth proximity detection to automatically unlock paired devices, like smartphones, when the ring is detected nearby, streamlining secure access while minimizing manual input.[79] Payment integration in smart rings relies on near-field communication (NFC) chips embedded in the hardware, enabling contactless transactions similar to those on smartphones or cards. Models like the McLEAR RingPay and CNICK payment rings support integration with services such as Visa and Mastercard, allowing users to tap the ring on payment terminals for quick purchases.[46][80] Security is bolstered by tokenization, where unique dynamic keys replace actual card details during transactions, reducing fraud risk even if the ring is lost or stolen.[80] Transaction limits typically align with regional contactless payment regulations; for example, many rings permit up to €50 per transaction without a PIN in Europe, with higher amounts requiring additional verification via a linked app.[81] These NFC-enabled rings comply with EMV standards, ensuring interoperability with global payment networks and adherence to chip-based security protocols.[82] Beyond financial transactions, smart rings facilitate access control through gestures or taps, leveraging NFC or Bluetooth for seamless integration with smart home systems. Users can tap compatible NFC rings on readers to unlock doors or gates, as seen in general applications for home and office entry where the ring acts as a digital key.[83] For instance, certain NFC smart rings support automation routines, such as triggering door locks via proximity or tap gestures when paired with systems like smart locks, providing hands-free entry without physical keys.[84] Adoption of security and payment features remains limited across the smart ring market, with market analyses indicating that approximately 60% of current devices incorporate some form of digital payment or NFC capability, though advanced biometric authentication is confined to fewer specialized models.[85] Regulatory compliance, particularly EMV standards for payments, is mandatory for transaction-enabled rings to ensure secure, standardized operations worldwide, driving gradual integration as manufacturers meet certification requirements.[86]Notifications and controls
Smart rings deliver notifications and enable device controls primarily through subtle haptic feedback and gesture-based interactions, compensating for the absence of screens or speakers. These mechanisms allow users to receive discreet alerts for incoming calls, text messages, and app notifications without needing to check their phone. For instance, the Circular Ring incorporates a vibration motor that provides patterned haptic alerts for various notifications, such as short pulses for texts or longer vibrations for calls.[87] Users can dismiss these alerts with a double-tap gesture on the ring, which leverages its built-in accelerometer to detect the motion.[88] Gesture controls further enhance usability by allowing hands-free interactions with paired devices. The Samsung Galaxy Ring, for example, supports a double-pinch gesture—squeezing the thumb and index finger together—to perform actions like snoozing alarms, skipping music tracks, or triggering the phone's camera for photos and videos.[89] Similarly, the discontinued Amazon Echo Loop (2019) used finger taps and twists to navigate apps or answer calls, with haptic confirmation providing tactile feedback upon successful execution.[90] These gestures rely on the ring's accelerometer and gyroscope sensors to interpret precise movements, enabling seamless control during activities where glancing at a screen is impractical. Due to their compact design, smart rings depend entirely on Bluetooth connectivity to a paired smartphone for processing and relaying notifications, lacking standalone displays or independent audio output. Any voice-based feedback, such as reading out message contents, must route through the phone's speakers or earbuds. This integration ensures notifications are filtered and prioritized via the companion app, but it also means the ring cannot function autonomously for controls beyond basic gestures.[21] Customization options are typically managed through dedicated mobile apps, where users can adjust haptic intensity, select vibration patterns for specific notification types, and set gesture sensitivity to suit personal preferences. For example, in the Circular Ring app, users fine-tune alert thresholds to minimize false positives from daily movements. However, enabling frequent haptic alerts and gesture monitoring can increase power consumption, potentially shortening the ring's battery life during heavy usage.[87]Manufacturers and models
Leading companies
Oura Health, founded in Finland in 2013, has established itself as a pioneer in sleep-tracking technology within the smart ring industry.[5][91] The company employs a subscription-based model to deliver ongoing health insights and software updates, which has contributed to its dominant position, holding approximately 80% of the smart ring market share as of 2025.[92] Samsung Electronics, based in South Korea, entered the smart ring market with the launch of its Galaxy Ring in 2024.[93] The device is strategically designed to integrate seamlessly with Samsung's Galaxy ecosystem of smartphones and wearables, emphasizing AI-driven features through Galaxy AI for enhanced health data analysis and user personalization.[94][17] Ultrahuman, an India-based company founded in 2019, differentiates itself with a subscription-free approach to smart ring offerings.[95] The firm focuses on metabolic health monitoring, providing tools for users to track glucose levels and energy optimization without recurring fees.[96] In 2024, Ultrahuman secured $35 million in Series B funding to support research and expansion in wearable health technologies.[97] Other notable players include Amazfit, developed by China's Huami Technology, which targets budget-conscious consumers with affordable smart ring options emphasizing basic fitness and sleep tracking.[98] In the United States, Movano Health specializes in women's health applications, with its Evie Ring receiving FDA clearance for features like pulse oximetry in 2024.[99][100] By 2025, the smart ring sector features over 10 active companies, reflecting rapid growth and diversification.[101] Strategic partnerships, such as Oura's collaboration with Best Buy for nationwide retail distribution since 2023, have bolstered accessibility and market penetration for leading firms.[102]Popular models
The Oura Ring 4, released in 2024 and widely available in 2025, features a fully titanium construction for durability and comfort, weighing between 3.3 and 5.2 grams depending on size (4 to 15). It offers up to eight days of battery life on a single charge and integrates AI-powered insights for personalized health recommendations, particularly excelling in detailed sleep stage analysis and recovery metrics. Priced at $349 plus a required $5.99 monthly subscription for full app access, it emphasizes comprehensive wellness tracking without a display, focusing on seamless integration with iOS and Android devices.[103][104][105] The Samsung Galaxy Ring, launched in 2024, is constructed from lightweight titanium in sizes 5 to 13, with weights ranging from 2.3 to 3 grams, and provides up to seven days of battery life for larger sizes (18-23 mAh capacity). It supports NFC for contactless payments and deep integration with Samsung's Galaxy ecosystem, including AI-driven energy score summaries and gesture controls for devices like the Galaxy Watch. At $399 with no subscription fee, it prioritizes Android compatibility, particularly for Samsung users, while offering robust heart rate and activity monitoring.[17][23] The Ultrahuman Ring Air, introduced in 2023 and still prominent in 2025, utilizes a lightweight resin exterior over a titanium inner frame, achieving a minimal weight of 2.4 to 3.6 grams across sizes 5 to 14, with up to six days of battery life from its 24 mAh cell. It tracks finger temperature for cycle and illness prediction, alongside standard metrics like heart rate variability and movement, all accessible via a subscription-free app compatible with both iOS and Android. Priced at $349, its design emphasizes all-day wearability and metabolic health insights without ongoing costs.[19][106][107] As a more affordable entrant launched in 2024, the RingConn Gen 2 features an ultra-thin titanium design weighing 2 to 3 grams in sizes 6 to 14, delivering 10 to 12 days of battery life and compatibility with a charging case for up to 150 additional days. It includes automatic sleep apnea detection and a robust app ecosystem for iOS and Android, tracking essentials like stress, SpO2, and activity without any subscription. At $199, it stands out for extended battery performance and accessibility for budget-conscious users seeking reliable health data.[108][109][11]| Model | Battery Life | Price | Key Features |
|---|---|---|---|
| Oura Ring 4 | Up to 8 days | $349 + subscription | AI insights, advanced sleep tracking |
| Samsung Galaxy Ring | Up to 7 days | $399 | NFC payments, Galaxy ecosystem integration |
| Ultrahuman Ring Air | Up to 6 days | $349 | No subscription, finger temperature tracking |
| RingConn Gen 2 | 10-12 days | $199 | Budget-friendly, sleep apnea monitoring, app ecosystem |