The wait is over for Telangana EAMCET hopefuls! The Telangana State Council of Higher Education (TSCHE) announced the TS EAMCET 2024 results today, May 18th. Candidates who took the entrance exam for admission into engineering, agriculture, and pharmacy programs can now check their scores on the official website: https://eapcet.tsche.ac.in/.
TS EAMCET:
Held between May 7th and 11th, this year’s TS EAMCET saw a massive turnout. Nearly 355,000 students appeared for the exam, with a staggering 94.45% opting for the engineering stream. Pharmacy and agriculture saw a participation rate of 91.24%.
How to Check TS EAMCET Results?
Accessing your TS EAMCET 2024 results is a quick and easy process:
Locate and click the link for “TS EAMCET Result 2024” on the homepage.
Enter your registration details on the new page.
Click “Submit” to view your results.
Download and print a copy of your results for future reference.
Passing Marks of TS EAMCET:
The minimum qualifying marks for General, OBC, and BC category candidates are set at 25% of the total exam score. SC and ST candidates don’t have a minimum threshold but will be ranked alongside other students based on their marks.
Stay Informed:
For the latest updates and information regarding TS EAMCET 2024 counseling and admissions, be sure to visit the official website regularly: https://eapcet.tsche.ac.in/.
In a bid to strengthen user privacy, WhatsApp has introduced a new layer of protection through the “Secret Code” feature for Chat Lock. This innovative addition aims to heighten the security of users’ conversations, particularly in situations where multiple individuals share a device or there is a concern about unauthorized access.
Mark Zuckerberg, Meta’s CEO, expressed his excitement about the update, saying, “We’re rolling out the secret code to Chat Lock on WhatsApp, allowing you to safeguard your chats with a unique password. Now, you can set your locked chats to only appear when you type the secret code in the search bar, ensuring that no one can accidentally stumble upon your most private conversations.”
WhatsApp explains that the secret code feature enables users to create a distinct password exclusively for their locked chats, adding an extra layer of privacy beyond the standard phone unlocking mechanism. Importantly, this password is separate from the one used to unlock the user’s device. Users can also choose to hide the Locked Chats folder from their chat list, ensuring these conversations remain concealed until the secret code is entered in the search bar. However, for those who prefer visibility, an option to display locked chats in the chat list is available.
In a user-friendly upgrade, WhatsApp simplifies the process of locking a chat by allowing users to long-press on the chat instead of navigating through the chat’s settings. The company expressed gratitude for the positive reception of Chat Lock, stating, “We’re thrilled that our community has been loving Chat Lock, and we hope that the secret code makes it even more useful to them.”
Availability of the Feature
The Secret Code feature is set to roll out today and is expected to be accessible globally in the coming months. WhatsApp emphasizes its commitment to continually enhancing Chat Lock, stating, “We’re excited to keep bringing more functions to Chat Lock to help people protect their privacy.”
WhatsApp users can look forward to an enriched and more secure messaging experience with the implementation of the Secret Code feature, reinforcing the platform’s dedication to staying at the forefront of user privacy and security.
Apple iPhone 15 Pro Max vs Google Pixel 8 Pro vs Galaxy S23 Ultra: Detailed Comparison
/ Detailed Comparison of Google Pixel 8 Pro, the Apple iPhone 15 Pro Max, and the Samsung Galaxy S23 Ultra.
By Babloo Farkade.
Date: 08 Oct 2023 13:59 PM IST
In the ever-competitive world of smartphones, Google’s Pixel 8 Pro has entered the ring, armed with a new processor, enhanced display, and improved cameras compared to its predecessor. However, it faces fierce competition from two heavyweight contenders that dominate the premium smartphone market: the iPhone 15 Pro Max and the Galaxy S23 Ultra. Let’s dive into the comparison of how these three giants stack up against each other.
Processing Power
The Pixel 8 Pro is equipped with the new Tensor G3 chipset, the third generation of Google’s custom-designed silicon aimed at enhancing on-device AI processing. While Tensor chipsets may not match the raw performance of the A17 Pro chip in the iPhone 15 Pro Max or the Snapdragon 8 Gen 2 chip in the Galaxy S23 Ultra in benchmark tests like Geekbench, they bring unique capabilities. These include media-editing features like Magic Eraser for removing elements from photos, Audio Magic Eraser for reducing background noise, and Best Take for combining the best parts of burst photos. These software advantages give the Pixel 8 Pro an edge, even though Magic Eraser is technically available for other phones through the Google Photos app.
Software Updates
One standout advantage of the Pixel 8 Pro is the promise of seven years of Android operating system and security updates. This significantly surpasses the four years of OS updates and five years of security updates offered by Samsung phones like the Galaxy S23 Ultra. Apple’s stance on the duration of software support is somewhat uncertain, with the latest iOS 17 update leaving behind older iPhone models like the iPhone 8 and iPhone X, released in 2017. Five years of OS updates is the conservative estimate for a new iPhone.
Camera Capabilities
The Pixel 8 Pro boasts a powerful rear camera setup, including a 50-megapixel main camera, a 48-megapixel ultrawide, and a 48-megapixel telephoto with 5x optical zoom. On paper, these cameras are expected to produce sharper photos than the 12-megapixel ultrawide and 12-megapixel telephoto cameras on the iPhone 15 Pro Max. However, testing will be needed to compare them to Apple’s unique “tetraprism” technology in its zoom camera. The Galaxy S23 Ultra, with its 200-megapixel main camera and two telephoto lenses (3x optical zoom and 10x optical zoom), presents a formidable challenge in the camera department, though its starting price of $1,200 reflects its advanced camera specs.
Display and Design
In terms of display, the Pixel 8 Pro features a 6.7-inch OLED display with a resolution of 3,120×1,440 pixels, boasting a brightness of up to 2,400 nits and a 1 to 120Hz refresh rate. The iPhone 15 Pro Max’s 6.7-inch OLED screen offers a slightly lower resolution, while the Galaxy S23 Ultra matches the Pixel’s resolution with its 6.8-inch AMOLED display. Both Apple and Samsung phones support a 120Hz adaptive refresh rate.
When it comes to design, each phone offers a distinct look. The Pixel 8 Pro retains its predecessor’s horizontal camera block, while the iPhone 15 Pro Max features a square camera block with larger lenses. The Galaxy S23 Ultra opts for minimalism with a clean back cover design, housing its five cameras.
Hardware and Battery
All three phones share similar hardware specifications, with variations in RAM and storage options. The Pixel 8 Pro starts with 12GB of RAM and offers storage capacities ranging from 128GB to 1TB. Apple doesn’t disclose RAM specifics but provides storage options of 256GB, 512GB, and 1TB for the iPhone 15 Pro Max. The Galaxy S23 Ultra begins with 8GB of RAM and offers storage choices of 256GB, 512GB, or 1TB.
None of the three phones supports expandable storage, necessitating reliance on cloud storage or external SSDs for additional storage needs. Battery capacity details for the iPhone remain undisclosed, while the Pixel 8 Pro boasts a 5,050mAh battery, and the Galaxy S23 Ultra comes with a 5,000mAh battery.
In a notable change, the iPhone 15 Pro Max has adopted a USB-C port instead of the traditional Lightning connector, offering 25 watts of wired charging and 15 watts of wireless charging. The Pixel 8 Pro supports up to 30 watts of wired charging and 23 watts of wireless charging, while the Galaxy S23 Ultra leads the pack with 45 watts of wired charging and 15 watts of wireless charging.
These flagship smartphones each bring their own strengths and unique features to the table, making the choice between them a matter of personal preference and priorities. Whether you prioritize camera quality, software updates, or design, these devices offer a diverse range of options in the premium smartphone market.
Undisclosed (Apple claims up to 29 hours of video playback)
5,000mAh
Fingerprint Sensor
Under display
None (Face ID)
Under display
Connector
USB-C
USB-C
USB-C
Headphone Jack
None
None
None
Special Features
5G, 7 years of OS updates, 13W Qi wireless charging, IP68 rated, Gorilla Glass Victus 2
5G, MagSafe, satellite connectivity, eSIM support
5G, wireless PowerShare, S Pen, 100x Space Zoom, UWB, 45W wired charging
US Price (Off-contract)
$999 (128GB)
$1,199 (256GB)
$1,200 (256GB)
UK Price
£825 (128GB)
£1,199 (256GB)
£1,249 (256GB)
Australia Price
AU$1,575 (128GB)
AU$2,199 (256GB)
AU$1,949 (256GB)
India Price
₹1,06,999 (128GB)
₹1,59,900 (256GB)
₹1,21,999 (256GB)
Conclusion: In summary, the Apple iPhone 15 Pro Max and Google Pixel 8 Pro are both remarkable smartphones, each with its own set of strengths and features. Your choice ultimately depends on your priorities, whether it’s the operating system, camera capabilities, performance, or design. Consider your individual needs and preferences when making the decision between these two flagship devices.
/ Explore what is Quantum Computing? Discover the future of computing with quantum technology. Explore the basics of quantum computing.
Author: Nilesh Badwar
Updated on ; 23 Dec 2023, 12:11 PM IST
In recent years, the world of quantum computing has surged to the forefront of technological advancement, promising unprecedented computational power and transformative applications across various industries. In this comprehensive guide for 2024, we will dive deep into quantum computing, exploring its fundamental principles, operational mechanisms, and the potential it holds for our digital future.
What is Quantum Computing?
Quantum computing represents a groundbreaking departure from classical computing paradigms. It harnesses the enigmatic principles of quantum mechanics, a cornerstone of modern physics that elucidates the behavior of matter and energy at the quantum level, encompassing atoms and subatomic particles. At its core, quantum computing leverages quantum bits, or qubits, to execute computations that are exponentially more efficient than their classical counterparts.
Understanding Qubits: The Quantum Building Blocks
The foundational element of quantum computing is the qubit, a quantum bit. While classical bits can only exist in one of two states, 0 or 1, qubits possess the remarkable property of superposition. This unique characteristic allows a qubit to inhabit multiple states simultaneously. Think of it as a coin suspended in mid-air, showcasing both heads and tails at once. This quality empowers quantum computers to process and store vast volumes of information in parallel, making them exceptionally well-suited for tackling specific computational challenges.
The Power of Entanglement
Another pivotal feature of qubits is entanglement, a phenomenon that allows the state of one qubit to be intrinsically tied to the state of another, even when they are physically separated by considerable distances. It’s akin to two coins, regardless of their spatial separation, consistently landing on the same side when flipped together. This attribute grants quantum computers a significant advantage, enabling them to perform certain calculations exponentially faster than classical computers.
Superposition: Expanding the Quantum World
Unlike traditional computing bits, which can be either 0s or 1s, qubits possess the extraordinary capability to exist in states of 0s, 1s, or a unique blend of both concurrently. This remarkable phenomenon is referred to as the state of superposition, and it fundamentally alters the landscape of information processing.
Imagine a traditional bit as a switch that can either be off (0) or on (1). In stark contrast, a qubit is akin to a dimmer switch, allowing for a seamless variation between off, on, and every conceivable shade in between. This distinctive quality endows qubits with the capacity to represent all conceivable combinations of information simultaneously.
When multiple qubits are entangled and harnessed together, their ability to maintain all possible configurations of information at once becomes a pivotal asset. Complex problems, which would be cumbersome or even impossible to represent using traditional computing methods, can be elegantly and efficiently handled through the quantum phenomenon of superposition. This unique attribute is at the heart of the quantum computing revolution, promising to unlock solutions to challenges that were once deemed insurmountable.
Unraveling the Mysteries of Quantum Interference
Quantum interference is an intriguing behavior of qubits that results from superposition. It influences the probability of a qubit collapsing into one state or another. Quantum computer designers and engineers dedicate considerable efforts to minimize interference and ensure accurate results. Innovative approaches, such as Microsoft’s utilization of topological qubits, involve manipulating their structure and shielding them with protective compounds to safeguard against external interference.
How Quantum Computers Operate/ Work?
Quantum computers share some commonalities with classical counterparts. Both types of computers possess chips, circuits, and logic gates that execute operations directed by algorithms. They employ a binary code of ones and zeros to represent information. However, the way they process information fundamentally diverges.
In classical computing, bits signify information in either a 0 or 1 state. In contrast, qubits reside in a superposition of 0 and 1 until measured, vastly expanding their processing potential. Furthermore, the states of multiple qubits can become entangled, allowing quantum computers to tackle complex problems with unparalleled efficiency.
What Are The Applications of Quantum Computing?
The potential applications of quantum computing are vast and transformative. Several fields stand to benefit significantly from advancements in quantum computing:
Finance: Companies can optimize investment portfolios, enhance fraud detection systems, and conduct sophisticated simulations to inform financial decisions.
Healthcare: Quantum computing could revolutionize drug discovery, personalized medicine, and DNA research, leading to breakthroughs in medical science.
Cybersecurity: While quantum computing poses security risks, it also offers solutions such as Quantum Key Distribution (QKD) for secure communication and data encryption.
Mobility and Transport: Industries like aviation can design more efficient aircraft, and transportation systems can benefit from quantum-based traffic planning and route optimization.
Understand Quantum Computing With Simple Example:
Quantum Coin Flipping: A Simple Example
To grasp the concept of quantum superposition, consider a special quantum coin, or qubit. Unlike a classical coin with only two outcomes (heads or tails), a quantum coin can exist in a superposition of both states simultaneously. When measured, it collapses probabilistically to one of the states. Here’s a simple example:
Prepare the quantum coin in a superposition: (H + T) / √2.
Flip the quantum coin.
When observed, the result is either H or T, but you won’t know until measured.
This example illustrates the power of quantum superposition, where a quantum entity can represent multiple possibilities until observed—a fundamental concept harnessed in quantum computing for more efficient calculations.
Classical Computing Vs. Quantum Computing
The distinctions between classical computing and quantum computing are summarized in the table below:
The future of quantum computing appears promising and poised for substantial growth in the world of technology. Quantum computing is still in its nascent stages, but it has the potential to address problems previously deemed insurmountable. Reports suggest that the quantum computing market will experience robust growth in the coming decades.
Notably, tech giants like Google are heavily invested in quantum computing research and development. Google’s TensorFlow Quantum (TFQ), an open-source library, aims to integrate quantum computing techniques with machine learning, paving the way for the creation of hybrid AI algorithms. These algorithms will seamlessly blend the capabilities of quantum and classical computers, opening new avenues for scientific exploration and problem-solving.
In conclusion, quantum computing represents a paradigm shift in the world of computation, offering unparalleled computational power and the ability to tackle complex problems across various domains. As we move forward in 2023 and beyond, the future holds exciting possibilities for quantum computing, and it will undoubtedly play a pivotal role in shaping the digital landscape of tomorrow.
The History of Quantum Computing
To understand the evolution of quantum computing, it’s essential to look back at its history. Here are some key milestones:
1980: Physicist Paul Benioff proposes the use of quantum mechanics for computation.
1985: Physicist David Deutsch at Oxford outlines the operational principles of quantum computers.
1994: Mathematician Peter Shor at Bell Labs devises an algorithm that can exploit quantum computers to break widely used encryption methods.
2004: Physicists Barbara Terhal and David DiVincenzo at IBM develop theoretical proofs demonstrating the computational superiority of quantum computers for specific problems.
2014: Google establishes its quantum hardware lab and hires leading experts to lead the research and development efforts.
2016: IBM makes prototype quantum processors available on the internet, encouraging programmers to prepare for quantum programming.
2019: Google’s quantum computer achieves “quantum advantage” by outperforming a classical supercomputer in a specialized task.
2020: The University of New South Wales in Australia offers the first undergraduate degree in quantum engineering to train a workforce for the budding industry
Conclusion:
Quantum computing, with its fundamental principles of superposition and entanglement, offers a revolutionary leap in computational power. As we journey into 2023 and beyond, the future of quantum computing holds immense promise across various industries, from finance to healthcare and beyond.
