Download Hotspot Shield Gratis

We used a DNS leak test tool to see if Hotspot Shield had any DNS leaks. And the result? Well, the IP address that the leak test tool detected was from the Bahamas, and we were nowhere near there when we performed the tests. That means that Hotspot Shield successfully shielded our IP address from DNS leaks.

You can connect with Hotspot Shield VPN customer service through a contact form on its website or at the following email address: support@hotspotshield.com. You can also contact the company via phone at 408-744-1002. Premium members get the option of a 24/7 live chat support function, as well.

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Once connected, a map appears showing your new virtual location, while other panels display a host of connection details: your server IP address, load and latency, the amount of data used on the current day, your current transfer speeds, and the name of your local network (handy as a reminder when you're connecting to wireless hotspots, say). It's a little cluttered and could intimidate not-so-technical users, but if you're not interested in the stats, they can all be safely ignored.

Aunque la versin gratis de Hotspot Shield VPN te permite conectarte a un servidor de Estados Unidos sin lmite, necesitars de la opcin premium para acceder a las conexiones VPN alojadas en otros territorios. En cualquier caso, no tendrs que pagar nada para comenzar a explorar las mltiples ventajas que te aporta esta herramienta.

S, Hotspot Shield VPN es gratis. No tendrs que pagar nada para disfrutar de esta herramienta VPN en tu smartphone. Eso s, necesitars una suscripcin premium para disponer de ms servidores y funcionalidades extra.

The VPN supports Tor usage across all servers. Using Tor over a VPN connection offers more protection than a regular Tor connection, as it shields against potential IP leaks that may occur during your Tor session. While such leaks are uncommon on the Tor network, should one occur, only the VPN's IP address would be revealed, keeping your actual IP address hidden.

A virtual private network, or VPN, shields your web traffic from the prying eyes of your ISP, making it harder for spies and advertisers to track you online. Hotspot Shield VPN has a handsome app and an array of security services that go far beyond VPN protection. It also boasts an impressive collection of servers around the globe, giving you many options for spoofing your location. The core VPN product is expensive, however, and its privacy policies are transparent but hurt by a few tradeoffs. While other VPNs have worked to make clear and concise arguments about how they protect their customers, Hotspot Shield continues to be a complicated story.

We checked that Hotspot Shield VPN wasn\u2019t leaking data by visiting the DNS Leak Test site and performing an extended test. Happily, only the VPN server's information came up during the test\u2014our personal data was shielded. We only tested one server, so there could be leaks on others.

Nowadays, Hotspot Shield's core service holds more than 1,800 servers that stretch across over 130 locations across the globe. All of their servers are P2P-friendly and come with a built-in security suite sure to stop malware, stave off phishers, and keep you safe during your online adventures. They also provide a variety of apps for Windows, Mac, Android, iOS, and even a command line Linux app, so you'll have no trouble shielding all of your devices.

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Gamma-ray imagers, which are devices for acquiring distributions of radioactive materials, are roughly classified as either pinhole or Compton cameras. Each method has different advantages and disadvantages, and they are used for different purposes. A pinhole camera obtains directivity by limiting the direction of incident gamma rays with a shield. Therefore, the pinhole camera can estimate the incidence direction of gamma rays for each event. This feature allows the quantitative measurement of radio activity. A survey of the operating floor of FDNPS Unit 2 [5] using a pinhole camera [6] was conducted by the Nuclear Regulation Authority (Tokyo, Japan) and TEPCO Holdings, Inc. (Tokyo, Japan). In the survey, a quantitative evaluation was performed. This survey demonstrated the effectiveness of pinhole cameras for quantitative measurement of radio activity in the FDNPS-decommissioning field. However, since the pinhole camera requires a gamma-ray shield in principle, the detector's weight must be as large as several tens of kilograms. While it is very suitable for fixed-point measurement, it is not suitable for remote measurement with a small robot or drone.

A gamma-ray imager that is compact, lightweight, and capable of quantitative measurement of radio activity is desirable for FDNPS decommissioning. Therefore, we propose the gamma-ray imager using small-angle scattering (GISAS), which combines the advantages of pinhole and Compton cameras. GISAS is composed of a set of shield-free directional gamma-ray detectors, which obtain directivity using the kinematics of Compton scattering. By measuring very small energies with high accuracy, ultrasmall-angle Compton scattering events can be detected. The uncertainty in the radiation source's direction can be minimized by focusing only on such ultrasmall-angle Compton scattering, which appears almost straight. This feature makes it possible to estimate the source direction for one event; as a result, it becomes possible to perform a quantitative measurement.

In this study, the principles behind shield-free directional gamma-ray detectors, an elemental technology of GISAS, were investigated using the Monte Carlo simulation tool kit Geant4 [11]. Simulations were performed to investigate the feasibility of this new idea. We first investigated whether angle selection can be performed by detecting small-angle scattering. We also investigated the relationship between detector geometry and directivity.

The upper part of Fig. 1(a) shows the structure of a pinhole camera. A position-sensitive detector is placed in the shield, which has a tiny pinhole. Gamma rays enter from the tiny pinhole and are absorbed by this detector. Therefore, the gamma-ray-incidence direction can be estimated for every single event. This feature not only improves the S/N ratio of reconstructed images compared to a Compton camera, as shown as lower part of Fig. 1(a), but also allows quantitative measurement. The pair consisting of the pinhole and detector pixel acts as a directional gamma-ray detector. A pinhole camera can be considered to be composed of a set of directional gamma-ray detectors. The field of view (FOV) of each detector is determined by the pinhole size, detector-pixel size, and the distance between the pinhole and the detector. If the detector is calibrated in advance, the radio activity of each FOV can be quantitatively measured based on the distance to the radiation source and the count of the detector.

The upper part of Fig. 1(c) shows the structure of a GISAS. The GISAS consists of a scatterer and an absorber. Since the GISAS estimates the scattering angle of gamma rays using the same principle as the Compton camera, it does not need a shield. Therefore, the size and weight of the imager can be reduced. As described above, unlike the Compton camera, the GISAS is designed to only detect events with extremely small scattering angles. Thus, each pixel of the absorber has its FOV like a pinhole camera, as shown in the lower part of Fig. 1(c).

The feasibility and operational principles of a shield-free directional gamma-ray detector, an elemental technology for GISAS, were investigated using the Monte Carlo simulation tool kit Geant4. The directional detector in this study is based on Compton scattering kinematics and estimates the gamma-ray scattering angle by measuring the energy of Compton scattered electrons. However, as shown in Fig. 3, when a thin detector is used as a scatterer, the effect of electrons escaping from the detector after imparting it with some of their energy cannot be ignored. This effect makes angle selection using energy information difficult. Therefore, we first investigate whether angle selection can be performed by detecting small-angle scattering by Si. 2351a5e196