Where To Find A Great Wireless Temperature Sensor?

As the smart home industry grows, I'm excited to explore options for a wireless temperature sensor! I want something reliable and efficient that can enhance my home automation. SwitchBot has some fantastic products that I’m considering!

I love how their sensors can easily integrate into a smart home setup, providing accurate readings and alerts. Plus, the design is sleek and user-friendly! It's great to see technology making our lives more comfortable and convenient.

If anyone has suggestions or experiences with wireless temperature sensors, I'd love to hear your thoughts! Thanks!

SwitchBot Wireless Temperature Sensor

I just discovered the SwitchBot wireless temperature sensor and I am thrilled about its features! I was looking for a reliable way to monitor the temperature in my home, and this device exceeded my expectations. Has anyone else tried it recently? The reviews I found online are overwhelmingly positive, highlighting its accuracy and ease of use. I love that it seamlessly integrates with my smart home setup. It's great to see a product that delivers on its promises. Any tips on how to maximize its potential?

Wireless Temperature Humidity Sensor for Crawl Space

Enhance the monitoring and control of your crawl space environment with our state-of-the-art Wireless Temperature Humidity Sensor. Designed to provide accurate and real-time data, this sensor offers a reliable solution for maintaining optimal conditions in crawl spaces. We carefully examined the shortcomings of all other sensors on the market to offer the best sensor solution with the longest range, the longest battery life, at the best price. Wireless Temperature and Humidity Sensor, this transmitter will send beacons of high-accuracy ±4%RH ±0.5°C temperature and humidity data at user-defined intervals.

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https://www.futureelectronics.com/p/semiconductors--analog--sensors--accelerometers/lis2mdltr-stmicroelectronics-5089926

High temperature accelerometers, programmable accelerometer sensors

LIS2MDL Series 3.6V 50 Hz High Performance 3-Axis Digital Magnetic Sensor-LGA-12

リモート監視とデータ収集のための革新的な IoT ソリューション

UbiBot は、リモート監視とデータ収集��特化した IoT ソリューションのトップ プロバイダーです。UbiBot は、高度なセンサーとクラウド プラットフォームを活用して、環境、産業、スマート インフラストラクチャ アプリケーションにリアルタイムの洞察を提供します。

LoRaWAN-Based Temperature and Humidity Sensors: Revealing Accuracy in Networking

The combination of Temperature and Humidity Sensors based on LoRaWAN has become a revolutionary force in the quickly evolving IoT world, changing how we monitor and comprehend our surroundings. This essay delves into the nuances of this innovative technology, examining its uses in several sectors and highlighting its indisputable benefits over conventional approaches.

Discover the cutting-edge wireless temperature monitoring system by Tempsens. Stay informed about temperature changes remotely and efficiently. Monitor and control temperature conditions in real-time for enhanced productivity and safety.

DHT11 / LDR Sensor's Under Water Wireless Data Transfer Using Arduino with IR and LCDhttps://www.youtube.com/watch?v=rp0dqpU4Si4

␂ > 𝐂𝐥𝐨𝐬𝐞𝐝 𝐒𝐭𝐚𝐫𝐭𝐞𝐫 // @lyrate-lifeform-approximation , @spiderman2-99

There’s a thought stirring in Bridge’s mind. An idea rolling about and nudging against the capacitors in her head, poking and prodding incessantly to get her attention, “Hey, hey, you know you want to ask her. Don’t you? Don’t lie to yourself, now. You should just do it. Hey! Are you listening to me? Hello-o…?”

Yes. Yes, she knows, she is aware of her burning curiosity. And it’s hard to deny that even though it doesn’t involve her, she is unusually intrigued by the concept. She overheard them in his office, Miguel and LYLA–his A.I. assistant–discussing a plan.  A plan to create a physical form for LYLA to enhance her abilities as his assistant and grant her further autonomy beyond her access to the security network and other adjacent systems alongside her recent emergence into emotional intelligence. It was all so fascinating. The steps Bridge had taken herself in her development in the span of weeks, she was watching unfold in another intelligence in real-time.

There it was again. That sense of solidarity in knowing she wasn’t completely alone in her existence as an artificial being, made of code and metal. It was like a magnetic pull that made that little voice in her head that encouraged her to act on her wants all the more present in her mind. She wanted to be a part of that process that she’d been through so long ago yet was still so familiar with like it happened yesterday. She wanted to guide her in that process and grant her her own knowledge. What’s the worst that can happen if she pilots your hardware for a while? You’re prepared for this. You can handle this. You can trust her, and she will be entirely safe in your care for that short time. And think about how much she would benefit from the experience, how much more streamlined that eventual transition from intangible to tangible will be once her own body was complete. It will make all the difference–and maybe reduce the headaches for everyone all-around, mostly Miguel as he acclimates to the change himself. Just… Try it. You can’t account for every single last risk factor, can you? No. So just do it and take it as it comes.

She stood in the middle of her dorm a moment, eyes closed as she ran a quick check of her hardware before making her final decision. RAM is in good condition. Storage is defragmented and all directories are organized. Sensors are calibrated and functional. Nanomachines are synchronized properly. Servos and joints retain a full range of motion. Coolant is at above optimal operational temperatures. Energy reserves are complete. Good. Everything’s in its right place and ready for its–potentially–temporary host. It’s time to make the call.

Her gaze trains itself on her watch, her arm rising to eye-level and the sleeve that was weighed down by the leaden metal cuff at the end sliding to her forearm to reveal device so she can start the transmission, navigating the menus on the digital interface indirectly via wireless communication–the unique way that she operated and communicated the Society’s technology.

“LYLA, may I speak to you for a moment? At your leisure, of course.”

In a study of six users, the Thermal Earring outperformed a smartwatch at sensing skin temperature during periods of rest. It also showed promise for monitoring signs of stress, eating, exercise, and ovulation. The smart earring prototype is about the size and weight of a small paperclip and has a 28-day battery life. A magnetic clip attaches one temperature sensor to a wearer’s ear, while another sensor dangles about an inch below it for estimating room temperature. The earring can be personalized with fashion designs made of resin (in the shape of a flower, for example) or with a gemstone, without negatively affecting its accuracy.

Continue Reading.

Chastity

The chastity cage, a standard issue for recruits, boasted a design that seamlessly integrated with the advanced technology of the Armour Suits.

Material: Nano Plastics and Ceramics Dual-Chamber Design: Separation for Testicles and Penis Locking Mechanism: Secure yet easily accessible for hygiene and maintenance Anti-Tamper Sensors: Alerts the AI in case of unauthorized attempts to manipulate the device Temperature Control: Maintains a comfortable temperature within the chambers Aeration System: Allows for ventilation to prevent moisture and ensure skin health Customizable Restraint Levels: Adjustable settings for varying degrees of security Medical-Grade Monitoring: Monitors physiological health and provides feedback to the wearer Compatibility: Integrates seamlessly with Armour Suit technology and HUD interfaces Hygienic Seals: Ensures cleanliness and reduces the risk of infection Comfort Padding: Medical-grade silicone for extended wear Adjustable Fit: Customizable sizing to accommodate individual anatomical variations Durability: Resistant to corrosion, impact, and extreme environmental conditions Charging: Wireless induction charging for convenience Compliance: Meets Tactical Paramedic Corps regulations for personal equipment

This state-of-the-art chastity cage goes beyond mere physical restraint, incorporating advanced technologies to ensure both security and the well-being of the wearer. Its dual-chamber design, combined with biometric authentication and anti-tamper features, establishes a new standard for personal discipline within the Tactical Paramedic Corps.

Shielded from external access, both the penis and testicles find residence in specially designed chambers crafted from premium silicone rubber. The surface texture mimics natural skin, ensuring a comfortable fit without leaving any discernible pressure marks. Within this chamber, a clear division accommodates the separate housing of the penis and testicles. The penis tube takes on a downward-bent configuration for optimal comfort.

Dedicated protection is afforded to the testicles through an independent chamber, shielding against pinching and providing a cooling effect. The larger size, complemented by a more spacious tube, enhances overall comfort. Additionally, ample room for expansion is available to prevent any sense of constraint in case of enlargement.

When nature calls, there's no requirement to unlock the belt. The penis tube seamlessly connects to an opening at the bottom of the belt. To prevent any potential blockage caused by an erect penis, a reservoir ensures the discharge point remains unobstructed.

The chastity belt integrates seamlessly with the armor suit's docking system through a specialized interface mechanism. The belt is equipped with a proprietary docking port that aligns precisely with the corresponding receptacle on the armor suit. This connection is established using a secure locking mechanism that ensures a robust and tamper-proof link.

This connection not only facilitates power transfer and data exchange but also ensures the proper functioning of integrated systems.

Upon docking, a series of verification protocols are initiated, confirming the integrity of the connection and the operational status of both the chastity belt and the armor suit.

Upon initiating the waste evacuation procedure, the integrated systems work in tandem to ensure a seamless and controlled process. The docking mechanism guarantees a reliable connection, allowing for the unhindered flow of waste from the chastity belt to the designated disposal system within the armor suit.

This comprehensive solution contributes to the overall functionality of the armor suit, addressing the physiological needs of the wearer while maintaining the discretion and efficiency required in operational environments.

The chastity cage is designed with versatility in mind, allowing it to be worn independently of the armor suit. Its standalone functionality ensures that the wearer can maintain the constraints and security provided by the chastity cage even when not in the complete armor suit ensemble.

Constructed from durable nano plastics and ceramics, the chastity cage provides a discreet and comfortable fit. The dual-chamber design, featuring separate compartments for the penis and testicles, ensures security and protection while offering a natural feel against the skin.

Whether worn as part of the complete armor suit or independently, the chastity cage remains an integral component, aligning with the established protocols and regulations governing the paramedics' conduct and attire

The uniformity enforced by the chastity cage contributes to the overall professionalism of the paramedics. It aligns with the standards set by the Corps, fostering a sense of discipline and uniformity among the tactical medical team.

The dual-chamber design ensures that the genitals are securely enclosed, reducing the risk of contamination or injury in the field.

By eliminating concerns related to personal needs, the paramedics can maintain a focused and concentrated mindset during critical situations. The chastity cage's design allows for seamless waste evacuation without compromising operational efficiency.

How do the Wireless Temperature Probe Sensors Work?

IoT Temperature Probe Sensors work by measuring the temperature of their surroundings and transmitting that data wirelessly to a central hub or cloud-based system. There are several types of temperature sensors used in IoT devices, including thermocouples, resistance temperature detectors (RTDs), and thermistors. Thermocouples are made of two different metals joined together at one end. When the temperature changes, a voltage is generated across the two junctions, which is proportional to the temperature difference. This voltage can be measured and used to calculate the temperature.

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Bossware Surveillance Buildings

A case study on technologies for behavioral monitoring and profiling using motion sensors and wireless networking infrastructure inside offices and other facilities"

Wolfie Christl, Cracked Labs, November 2024

This case study is part of the ongoing project “Surveillance and Digital Control at Work” (2023-2024) led by Cracked Labs, which aims to explore how companies use personal data on workers in Europe, together with AlgorithmWatch, Jeremias Prassl (Oxford), UNI Europa and GPA, funded by the Austrian Arbeiterkammer.

Case study “Tracking Indoor Location, Movement and Desk Occupancy in the Workplace” (PDF, 25 pages) Summary

As offices, buildings and other corporate facilities become networked environments, there is a growing desire among employers to exploit data gathered from their existing digital infrastructure or additional sensors for various purposes. Whether intentionally or as a byproduct, this includes personal data about employees, their movements and behaviors.

Technology vendors are promoting solutions that repurpose an organization’s wireless networking infrastructure as a means to monitor and analyze the indoor movements of employees and others within buildings. While GPS technology is too imprecise to track indoor location, Wi-Fi access points that provide internet connectivity for laptops, smartphones, tables and other networked devices can be used to track the location of these devices. Bluetooth, another wireless technology, can also be used to monitor indoor location. This can involve Wi-Fi access points that track Bluetooth-enabled devices, so-called “beacons” that are installed throughout buildings and Bluetooth-enabled badges carried by employees. In addition, employers can utilize badging systems, security cameras and video conferencing technology installed in meeting rooms for behavioral monitoring, or even environmental sensors that record room temperature, humidity and light intensity. Several technology vendors provide systems that use motion sensors installed under desks or in the ceilings of rooms to track room and desk attendance.

This case study explores software systems and technologies that utilize personal data on employees to monitor room and desk occupancy and track employees’ location and movements inside offices and other corporate facilities. It focuses on the potential implications for employees in Europe. To illustrate wider practices, it investigates systems for occupancy monitoring and indoor location tracking offered by Cisco, Juniper, Spacewell, Locatee and other technology vendors, based on an analysis of technical documentation and other publicly available sources. It briefly addresses how workers resisted the installation of motion sensors by their employers. This summary presents an overview of the findings of this case study….

NASA ocean world explorers have to swim before they can fly

When NASA's Europa Clipper reaches its destination in 2030, the spacecraft will prepare to aim an array of powerful science instruments toward Jupiter's moon Europa during 49 flybys, looking for signs that the ocean beneath the moon's icy crust could sustain life.

While the spacecraft, which launched Oct. 14, carries the most advanced science hardware NASA has ever sent to the outer solar system, teams are already developing the next generation of robotic concepts that could potentially plunge into the watery depths of Europa and other ocean worlds, taking the science even further.

This is where an ocean-exploration mission concept called SWIM comes in. Short for Sensing With Independent Micro-swimmers, the project envisions a swarm of dozens of self-propelled, cellphone-size swimming robots that—once delivered to a subsurface ocean by an ice-melting cryobot—would zoom off, looking for chemical and temperature signals that could indicate life.

"People might ask, why is NASA developing an underwater robot for space exploration? It's because there are places we want to go in the solar system to look for life, and we think life needs water. So we need robots that can explore those environments—autonomously, hundreds of millions of miles from home," said Ethan Schaler, principal investigator for SWIM at NASA's Jet Propulsion Laboratory in Southern California.

Under development at JPL, a series of prototypes for the SWIM concept recently braved the waters of a 25-yard (23-meter) competition swimming pool at Caltech in Pasadena for testing. The results were encouraging.

SWIM practice

The SWIM team's latest iteration is a 3D-printed plastic prototype that relies on low-cost, commercially made motors and electronics. Pushed along by two propellers, with four flaps for steering, the prototype demonstrated controlled maneuvering, the ability to stay on and correct its course, and a back-and-forth "lawn mower" exploration pattern. It managed all of this autonomously, without the team's direct intervention. The robot even spelled out "J-P-L."

Just in case the robot needed rescuing, it was attached to a fishing line, and an engineer toting a fishing rod trotted alongside the pool during each test. Nearby, a colleague reviewed the robot's actions and sensor data on a laptop. The team completed more than 20 rounds of testing various prototypes at the pool and in a pair of tanks at JPL.

"It's awesome to build a robot from scratch and see it successfully operate in a relevant environment," Schaler said. "Underwater robots in general are very hard, and this is just the first in a series of designs we'd have to work through to prepare for a trip to an ocean world. But it's proof that we can build these robots with the necessary capabilities and begin to understand what challenges they would face on a subsurface mission."

Swarm science

The wedge-shaped prototype used in most of the pool tests was about 16.5 inches (42 centimeters) long, weighing 5 pounds (2.3 kilograms). As conceived for spaceflight, the robots would have dimensions about three times smaller—tiny compared to existing remotely operated and autonomous underwater scientific vehicles. The palm-size swimmers would feature miniaturized, purpose-built parts and employ a novel wireless underwater acoustic communication system for transmitting data and triangulating their positions.

Digital versions of these little robots got their own test, not in a pool but in a computer simulation. In an environment with the same pressure and gravity they would likely encounter on Europa, a virtual swarm of 5-inch-long (12-centimeter-long) robots repeatedly went looking for potential signs of life. The computer simulations helped determine the limits of the robots' abilities to collect science data in an unknown environment, and they led to the development of algorithms that would enable the swarm to explore more efficiently.

The simulations also helped the team better understand how to maximize science return while accounting for tradeoffs between battery life (up to two hours), the volume of water the swimmers could explore (about 3 million cubic feet, or 86,000 cubic meters), and the number of robots in a single swarm (a dozen, sent in four to five waves).

In addition, a team of collaborators at Georgia Tech in Atlanta fabricated and tested an ocean composition sensor that would enable each robot to simultaneously measure temperature, pressure, acidity or alkalinity, conductivity, and chemical makeup. Just a few millimeters square, the chip is the first to combine all those sensors in one tiny package.

Of course, such an advanced concept would require several more years of work, among other things, to be ready for a possible future flight mission to an icy moon. In the meantime, Schaler imagines SWIM robots potentially being further developed to do science work right here at home: supporting oceanographic research or taking critical measurements underneath polar ice.

A prototype of a robot designed to explore subsurface oceans of icy moons is reflected in the water’s surface during a pool test at Caltech in September. Conducted by NASA’s Jet Propulsion Laboratory, the testing showed the feasibility of a mission concept for a swarm of mini swimming robots. Credit: NASA/JPL-Caltech

A model of the final envisioned SWIM robot, right, sits beside a capsule holding an ocean-composition sensor. The sensor was tested on an Alaskan glacier in July 2023 through a JPL-led project called ORCAA (Ocean Worlds Reconnaissance and Characterization of Astrobiological Analogs). Credit: NASA/JPL-Caltech