The good news is my smart typewriter arrived, the bad news is its battery is deceased

appleiphone

honestly i want to use tumblr more often but GOD does the mobile app drain battery so fucking fast. literally no other social media app i use is like this

Advanced SOC Diagnostics for Lithium-ion Battery Health

Accurately determining the State of Charge (SOC) is vital for effective battery health management in today’s energy-driven world. Just as you rely on a fuel gauge in your car, SOC reflects how much usable energy remains in a lithium-ion battery, preventing sudden failures and optimizing performance.

Modern Battery Management Systems (BMS) use layered diagnostic algorithms to ensure SOC accuracy, compensating for variables that influence measurement reliability.

Advanced Methods for SOC Estimation

1. Ampere-Hour Integration (Coulomb Counting)

This method continuously tracks the current entering and exiting the battery. While fundamental to SOC calculation, it’s prone to drift errors due to sensor inaccuracies and battery self-discharge. Thus, it often requires correction from other techniques.

2. Charge & Discharge Voltage Correction

Lithium-ion batteries exhibit predictable voltage behaviours during charge/discharge cycles. By comparing these voltage/current patterns against predefined SOC curve libraries, systems refine their SOC accuracy and adjust readings based on real-world performance.

 3. Open Circuit Voltage (OCV) Correction

OCV represents the battery voltage at rest and strongly correlates with SOC. Using a battery-specific OCV-SOC curve, systems can recalibrate SOC values periodically during rest intervals, ensuring greater accuracy across usage conditions.

4. Full/Empty Position Reset

When the battery reaches a full or empty state, the SOC is calibrated to 100% or 0%, respectively. These reset points are critical for avoiding long-term drift in battery state of charge monitoring and help align individual cell voltages within a battery cluster.

Real-World Scenario: SOC Step-Down Anomaly

At a project site, engineers noticed a recurring SOC drop, even while the battery was idle. Though OCV calibration was enabled, a step-down pattern appeared during rest periods. Investigation revealed the root cause: the default OCV table from the manufacturer had not been correctly configured in the BMS.

Surprisingly, disabling the OCV calibration didn’t solve the issue. Digging deeper, engineers discovered a “SOC loss power” reading of 2086W, signifying phantom energy loss. The cause? An erroneous power compensation setting within the system’s persistent memory.

The Fix: EEPROM Reset & Cache Cleaning

To correct the issue:

The team executed the “AAA4” command to reset the EEPROM, which holds configuration data and compensation values.

A full system refresh using “read all” restored accurate SOC levels.

An automatic cache cleaning function was added to purge stale or incorrect data from volatile memory.

Post-reset, SOC readings stabilized. No further drop was observed during a 2-hour rest, validating the correction.

Best Practices for SOC Troubleshooting

Always verify SOC-OCV data from the battery manufacturer.

Monitor and correct hidden settings like SOC loss power compensation.

Follow a structured battery diagnostics workflow.

Integrate memory cache maintenance into your software routine.

Conclusion

Maintaining optimal lithium-ion battery health hinges on accurate SOC diagnostics, robust algorithms, and meticulous system calibration. As this case study demonstrates, even minor misconfigurations can cause persistent problems. Through proactive diagnostics, firmware resets, and routine memory maintenance, engineers can ensure consistent SOC performance, safety, and battery lifespan optimization.

Battery Drain: Common Causes & Solutions

AI-generated image. “My phone is at 98%, maybe I should charge it.” We’ve all been there—watching the battery percentage plummet faster than our hopes for a productive day. Whether it’s the dreaded “low battery” warning at the worst possible moment or your laptop shutting down mid-sentence, battery life is a fickle beast. But what actually determines how long your device holds a charge? And how…

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What Should You Know About Regenerative Braking Systems?

Regenerative braking systems have become a key feature in modern vehicles, particularly in electric and hybrid cars. This advanced technology not only enhances efficiency but also contributes to the overall sustainability of automotive transportation. In today’s push toward eco-friendly solutions, understanding how regenerative braking systems work and the benefits they offer can help drivers…

Charge Smart, Not Hard

Using Wireless Charger, you can charge your phone without plugging in any cables. But here’s the question: Does using wireless charging degrade your phone’s battery? Are you sure, such chargers are device friendly?

My concepts for the development progress of an Iterators Puppet

-my ideas below

-Feasibility Study  

[1]: First autonomous control module, any instruction to be given must be done manually through physical means (the keys), outputs were shown through the screen. A very primitive system, however, did its job proving the greater machine concept was achievable. While it does look like a lens above the monitor, this was a simple status gauge for benchmarking.

-Prototyping and Development  

[2]: Now with the capability to wirelessly and audibly communicate to receive instructions and inputs. The system was no longer directly integrated into the facility, and resided on the first instance of an iterator's arm. This was considered a feat due to the complications with isolating the control module from the rest of the iterators components, while keeping processing power. A permanent connection/umbilical was needed to sustain life and function though. 

To “talk” back, they were crafted with multidimensional projectors, the mobile arm allowing the angles and variance for this projection. Only later into development were advanced speakers installed for optimized understanding, however the extra computing power required to synthesize proper speech was found to strain the contained module, so this function had rare use in the end.

[3]: At this point there was a change in perspective in the project. What once were machines to simply compute and simulate, were now planned to be the home, caregiver, and providers. The further the project came to fruition the more religious importance was placed upon these “random gods”. From this stance not only did the puppets have to manage and control their facilities, they had to communicate with the people and priests. To represent benevolent beings who will bring their end and salvation. In this process iterators began to take a more humanoid shape, to better reflect their parents. Development was focused on compacting the puppet closer to the size of an ancient for this purpose. This stage was the first to incorporate a cloak/clothing into their design considerations, to further akin themselves in looks. The cloak would hide the iterators' engineered bodies and give a body to their silhouette. 

[4]: As bioengineering and mechanics were rapidly progressing due to the void fluid revolution, this allowed plenty of margin for developing the outer design of the iterator puppets. This prototype was the first to incorporate limbs for the purpose of body language. This was another step in the drive to give a body to their random gods.

-Final Iterations

[5]: First generation iterators had the final redesign of puppet bodies. Far different from their first designs, they are fully humanoid. Their bodies are shaped to be organic and as full of life as they could at the time. Their center of sapience has fully settled within their body, as can be seen as their unconscious use of limbs without the direct intention for communication. This can also see how they manage their work, where many of the functions (which can be done with just an internal request) are operated through physical gestures of their limbs. Their puppet chambers also allow for full comprehensive projection, where many of their working monitors are displayed. It is seen how iterators prefer to utilize their traversal arm to transfer between the current working projection window.

These designs were hardy and nearly self-sufficient, only requiring minimal power from their umbilical to charge. (However was still limited in the terms of internal power production, for this first generation extensive batteries sufficed)

[6]: Later generation not only incorporated advanced bioengineering internally, but externally. While still a hardened shell, their body plates have been incorporated into the organics of the puppet, maintaining the protective requirements while barely leaving a trace of hinges or plates. This “soft” skin had drawbacks, such as reduced durability to the first generations, this was offset by the greatly enhanced repair speeds and capability this type of skin allowed.

Internal power generation was implemented into these late generation models. If the case arose, the Puppet could be disconnected from their umbilical and still be conscious from an undefined period of time. (However this would limit the operating capacity of the puppet when running self sufficiently) This greatly eased maintenance works, as the Puppet could still run the greater facility wirelessly while work was done on the chamber, arm or whatever as needed.

Battery Control Technology Market Business Overview and Upcoming Outlook 2032

Overview of the Battery Control Technology Market:

Battery Control Technology Market Overview: The battery control technology market encompasses various technologies and solutions designed to monitor, manage, and optimize the performance of batteries used in a wide range of applications, including consumer electronics, electric vehicles, renewable energy storage systems, and industrial equipment. These technologies play a crucial role in extending battery life, improving efficiency, ensuring safety, and enhancing overall performance.

Growth Trends and Factors Driving Demand:

Rising Adoption of Electric Vehicles (EVs): The increasing shift towards electric vehicles as a more environmentally friendly transportation option has led to a growing demand for advanced battery control technologies. These technologies are essential for managing battery health, charging/discharging cycles, and thermal management in EVs.

Renewable Energy Storage: The integration of renewable energy sources like solar and wind power into the grid has created a need for efficient energy storage solutions. Battery control technologies are crucial for optimizing energy storage systems, enabling smooth power delivery, and ensuring grid stability.

Consumer Electronics: The proliferation of smartphones, laptops, wearables, and other portable electronic devices has driven the demand for high-performance batteries with advanced control and management features, such as fast charging and power optimization.

Industrial Applications: Industries such as telecommunications, data centers, and manufacturing rely on backup power solutions and energy storage systems. Battery control technologies are used to ensure reliable power supply during outages and manage energy consumption.

IoT and Connectivity: The Internet of Things (IoT) and connected devices require efficient and reliable battery control technologies to optimize power consumption, enhance device performance, and enable remote monitoring and management.

Focus on Battery Safety: Safety is a critical concern in battery applications. Battery control technologies help monitor battery conditions, detect potential issues like overcharging and overheating, and implement safety measures to prevent accidents.

Advancements in Battery Management Systems (BMS): Battery management systems have evolved to include sophisticated control algorithms, real-time monitoring, predictive maintenance capabilities, and communication interfaces for seamless integration into various applications.

Research and Development: Ongoing research and development efforts aim to improve battery chemistries, enhance energy density, and develop more efficient battery control technologies, thereby driving further demand in the market

Battery control technology offers several key benefits across various industries and applications. Here are some of the key benefits:

Enhanced Battery Performance: Battery control technology helps optimize battery performance by actively managing charging and discharging cycles, maintaining optimal voltage levels, and preventing overcharging or over-discharging. This results in improved battery efficiency, longer lifespan, and better overall performance.

Extended Battery Life: By monitoring and controlling critical battery parameters, such as temperature and state of charge, battery control technology can help extend the operational life of batteries. This is particularly important in applications like electric vehicles and renewable energy storage systems, where battery replacement costs can be significant.

Improved Safety: Battery control technology includes safety features such as overvoltage protection, overcurrent protection, and thermal management. These safety mechanisms help prevent battery damage, reduce the risk of fires or explosions, and enhance overall system safety.

Optimized Charging and Discharging: Smart battery control systems can dynamically adjust the charging and discharging rates based on real-time conditions, load requirements, and user preferences. This ensures efficient energy utilization and prevents situations where batteries are stressed or underutilized.

Fast Charging: Battery control technology enables faster charging without compromising safety or battery health. It can manage high-power charging processes while maintaining safe temperature levels and preventing degradation.

Intelligent Energy Management: In applications like renewable energy storage systems and microgrids, battery control technology allows for intelligent energy management. It enables the storage and release of energy at optimal times, maximizing the utilization of renewable energy sources and reducing reliance on conventional power sources.

Remote Monitoring and Management: Many battery control systems are equipped with remote monitoring and management capabilities. This enables real-time tracking of battery performance, health, and status, allowing for proactive maintenance and minimizing downtime.

Predictive Maintenance: Advanced battery control technology can analyze data over time to predict battery health and performance degradation. This enables operators to schedule maintenance and replacement activities before major issues arise, reducing unexpected failures and downtime.

Integration with IoT and Smart Systems: Battery control technology can integrate with Internet of Things (IoT) platforms and smart systems, allowing for seamless communication, data sharing, and coordination with other devices and applications.

Environmental Impact: By optimizing battery usage and extending their lifespan, battery control technology contributes to reducing electronic waste and conserving valuable resources. Additionally, in applications like electric vehicles and renewable energy storage, it supports the transition to cleaner and more sustainable energy solutions.

Cost Savings: Improved battery performance and extended lifespan lead to reduced replacement and maintenance costs. Efficient energy utilization and demand-side management can also result in cost savings, especially in industrial and commercial applications.

We recommend referring our Stringent datalytics firm, industry publications, and websites that specialize in providing market reports. These sources often offer comprehensive analysis, market trends, growth forecasts, competitive landscape, and other valuable insights into this market.

By visiting our website or contacting us directly, you can explore the availability of specific reports related to this market. These reports often require a purchase or subscription, but we provide comprehensive and in-depth information that can be valuable for businesses, investors, and individuals interested in this market.

“Remember to look for recent reports to ensure you have the most current and relevant information.”

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Market Segmentations:

Global Battery Control Technology Market: By Company

• A123 systems LLC.

• Ford Motor Co.

• GE Energy LCC.

• Toyota Motor Corp.

• Sony Electronic Inc.

• Samsung SID Co. Ltd.

• Sanyo electric Co. Ltd.

• Panasonic Corp.

• L.G Chem LTD.

• Honda Motor Co. Ltd.

Global Battery Control Technology Market: By Type

• Smart Batteries

• Chargers

• Conditioners.

Global Battery Control Technology Market: By Application

• Automotive

• Traction, Marine and Aviation

• Portable Products

• Stationary (UPS, Emergency, Remote)

• On-road Electric Vehicles

Global Battery Control Technology Market: Regional Analysis

The regional analysis of the global Battery Control Technology market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Battery Control Technology market report are as follows:

North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Battery Control Technology in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product.

Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Battery Control Technology in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors.

Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Battery Control Technology in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction.

Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors.

South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Battery Control Technology in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.

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• To gain insights into market trends and dynamics: this reports provide valuable insights into industry trends and dynamics, including market size, growth rates, and key drivers and challenges.

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• To understand consumer behavior: this research reports can provide valuable insights into consumer behavior, including their preferences, purchasing habits, and demographics.

• To evaluate market opportunities: this research reports can help businesses evaluate market opportunities, including potential new products or services, new markets, and emerging trends.

• To make informed business decisions: this research reports provide businesses with data-driven insights that can help them make informed business decisions, including strategic planning, product development, and marketing and advertising strategies.

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long-distance mech pilots don’t need to worry quite so much about traveling light. when you’re walking around in several tons of metal, especially one built to wander, you aren’t quite to the point of needing to choose which of two keepsakes you have room in your bag for— there’s plenty of space for both.

Things are different for interstellar knights.

You see, whether wandering alone or setting off on some quest for their lord, a knight’s only home is their armor. Anything they bring with them, they must carry within that armor, even through battles— and as such, every gram and every cubic centimeter can make the difference between life and death, and every calorie chosen to replace a keepsake can make the difference between survival and starvation. As such, a knight’s inventory is heavily optimized— and so is their armor itself. What matters more, the heating system or the EVA boosters? The extra fuel storage or the emergency release mechanisms? Pick one, and you’ll have no room for the other unless you can cut corners somewhere else. Every single element of a knight’s armor is there because they made the conscious decision to put it there. Every weapon they’ve attached to their shell had to replace some traditional aspect of a life support system. Every inch of their shells are packed full of every system that can fit until it’s tight against the pilot’s skin to leave them bruised whenever they exit their shell.

it doesn’t take long for them to realize which superfluous components are the weakest link.

They start small, at first— often as simple as a haircut to help a tighter helmet fit better. Some try to lose weight, but quickly regret it when they find themselves near starvation on some distant moon. The ones that survive past their first year are the ones that are willing to take things a bit further— the toes on both feet, to make room for a slight jump booster. One of their ribs, perhaps— replaced with a battery that connects to the armor through a cable that winds around bones and muscles. It’s only a matter of time before they do something about those bones and muscles too.

those who have only heard the stories will say that a knight’s armor is their home. Those who have met one, seen them exit their armor and seen just how little is left of the body inside— they will say that a knight’s armor is a part of their body. Integrated into them until they cannot survive without it. Both are wrong. Even some knights cannot pin down the true answer— what they really feel as they connect their armor to the components of it that they have placed inside of them. The best ones do, though. They know it well.

A knight’s armor is not a part of their body. Their body is a part of their armor— their home, to be renovated and optimized as they see fit. To be replaced, improved, amputated and eviscerated so that it can be remade into the glorious works of art that the heroes of the galaxy become as they charge into battle and become a story worth remembering.

As the armor learns to reach into your veins, pulling oxygen from the carbon dioxide you exhale and weaving it back into your blood, the space once taken up by inefficient organic lungs becomes the home of the heating system, warming you from within no matter what part of the void between stars you find yourself in. As it recycles amino acids into proteins again and infuses them back into what tissues remain, you’re free to remove your old digestive organs and find a home for your armor’s main computer, kept safe at the center of your shell. Many knights choose to put their own organic brain down there next to it, incidentally making room for more optical systems in their skulls.

Your armor is no longer simply “a part of you” and you are no longer simply “a part of it.” It is you. You are it. Your bones, its power cells, your organs its systems. You are its brain and its CPU in equal measure and its beautiful exterior plates, painted with the symbols of the lord you serve or simply the cause you stand for, will inspire others to take up arms themselves and let themselves become part of it.

your body, your home, your masterpiece

Hai! It’s ur fav Idia anon😈😈😈😈😈😈😈😈 okay hear me out, Idia with a half frank stein half cyborg reader. Like reader has an electric heart and organs but a human brain and is like made out of like ten dead human parts, oil for blood type. So Idia is just like checking up on their vital robot organs on his computer, like using wires to connect to reader’s organs (entry thing on back??) while reader is on his lap, just relaxing and chilling, and u can interpret the rest😝😝😝😝😝

[Yes you are my favourite Idia anon😁]

(Tw: mild body horror mentions, nothing gory, just wires and weird organs. Soft vibes override.)

The room is bathed in a neon-blue glow, flickering slightly as a screen updates line after line of data—pulses, pressure, charge levels, synaptic fire. All of it you.

“Okay, okay… entry port's clean, transmission’s stable…” Idia mutters, fingers dancing across his keyboard, fast as lightning, faster than your own synthetic nerve relays. His hair pulses in hues of cerulean and violet, glowing brighter every time your vitals spike. Which they do. Every time you shift in his lap.

You’re leaned back against his chest, legs folded sideways over his, like a puzzle piece slotted in place. Calm. Almost sleepy. Like it’s normal to have a bunch of cables trailing from the base of your spine, connecting your bio-mechanical organs directly into Idia’s rig.

Your heart? Electric. Hums like an engine when you're content. Your lungs? Powered by soft hydraulic pulses that compress with a hiss and expand with a shudder. And Idia? Well, he’s obsessed.

Not in the "science project" kind of way. More like the "I can't believe you're real and I get to be the only one who gets this close to your wiring" kind of way.

"How’re you feeling?" he asks, voice unusually quiet. His hand’s resting over your sternum, right above the casing where your electric heart clicks and pulses like a steady metronome.

"Warm," you murmur. “Even with the oil circulation. Feels… nice.”

That makes him freeze for a nanosecond. Nice. Nice? YOU think it’s nice??? His brain blue-screens. You’re literally half-built from corpses and spare parts—there’s tubing under your skin instead of veins, a synth-liver that processes coolant, and an actual operating system that pings him when your battery’s low. And you're just… on his lap like a cat.

“Uhh… yeah… obviously it’s nice. My setup is, like, peak comfort optimization. Nothing less for my… my um…”

He trails off.

You blink up at him. “Your…?”

"...My favorite test subject." He coughs. Loudly. “N-not in a creepy way!! Just, like, statistically you’re the one I monitor the most, so it’s just accurate, you know?? Purely clinical—"

You tilt your head back a little more so you can look up at him with that half-synthetic eye of yours that flickers softly when you smile.

“Idia.”

He stiffens.

"You don't need to short-circuit over every compliment."

"...I d-don’t short-circuit." (He does.) (He literally does. Your neural link picks up a micro surge in his output whenever you’re too close. Which is always.)

Still, he leans down, brushing his nose against the crown of your head. “Just sayin’. No one else gets to do this. Monitor you, I mean. Tinker. Maintain. You’ve got, like, a whole corpse-Wi-Fi situation going on, and I’m the only one who knows the password.”

You hum again. You like that. The idea of belonging—not as a project, but as a person only he understands.

“Okay, diagnostics are good. All organ-tech’s running smooth. Heartbeat's in the sweet zone. No overheating.” He lets the wires retract with a whirr, but doesn’t move you off his lap. If anything, he wraps his arms a little tighter around your waist. “Guess I’ll just keep you here a little longer. For observation. You know. For science.”

You smile, letting your body rest fully against him, your cold frame soaking in his heat.

“Sure, doc. For science.”

Things Biden and the Democrats did, this week #9

March 9-15 2024

The IRS launched its direct file pilot program. Tax payers in 12 states, Florida, New Hampshire, Nevada, South Dakota, Tennessee, Texas, Washington, Wyoming, Arizona, Massachusetts, California and New York, can now file their federal income taxes for free on-line directly with the IRS. The IRS plans on taking direct file nation wide for next year's tax season. Tax Day is April 15th so if you're in one of those states you have a month to check it out.

The Department of Education’s Office of Civil Rights opened an investigation into the death of Nex Benedict. the OCR is investigating if Benedict's school district violated his civil rights by failing to protect him from bullying. President Biden expressed support for trans and non-binary youth in the aftermath of the ruling that Benedict's death was a suicide and encouraged people to seek help in crisis

Vice President Kamala Harris became the first sitting Vice-President (or President) to visit an abortion provider. Harris' historic visit was to a Planned Parenthood clinic in St. Paul Minnesota. This is the last stop on the Vice-President's Reproductive Rights Tour that has taken her across the country highlighting the need for reproductive health care.

President Biden announced 3.3 billion dollars worth of infrastructure projects across 40 states designed to reconnect communities divided by transportation infrastructure. Communities often split decades ago by highways build in the 1960s and 70s. These splits very often affect communities of color splitting them off from the wider cities and making daily life far more difficult. These reconnection projects will help remedy decades of economic racism.

The Biden-Harris administration is taking steps to eliminate junk fees for college students. These are hidden fees students pay to get loans or special fees banks charged to students with bank accounts. Also the administration plans to eliminate automatic billing for textbooks and ban schools from pocketing leftover money on student's meal plans.

The Department of Interior announced $120 million in investments to help boost Climate Resilience in Tribal Communities. The money will support 146 projects effecting over 100 tribes. This comes on top of $440 million already spent on tribal climate resilience by the administration so far

The Department of Energy announced $750 million dollars in investment in clean hydrogen power. This will go to 52 projects across 24 states. As part of the administration's climate goals the DoE plans to bring low to zero carbon hydrogen production to 10 million metric tons by 2030, and the cost of hydrogen to $1 per kilogram of hydrogen produced by 2031.

The Department of Energy has offered a 2.3 billion dollar loan to build a lithium processing plant in Nevada. Lithium is the key component in rechargeable batteries used it electric vehicles. Currently 95% of the world's lithium comes from just 4 countries, Australia, Chile, China and Argentina. Only about 1% of the US' lithium needs are met by domestic production. When completed the processing plant in Thacker Pass Nevada will produce enough lithium for 800,000 electric vehicle batteries a year.

The Department of Transportation is making available $1.2 billion in funds to reduce decrease pollution in transportation. Available in all 50 states, DC and Puerto Rico the funds will support projects by transportation authorities to lower their carbon emissions.

The Geothermal Energy Optimization Act was introduced in the US Senate. If passed the act will streamline the permitting process and help expand geothermal projects on public lands. This totally green energy currently accounts for just 0.4% of the US' engird usage but the Department of Energy estimates the potential geothermal energy supply is large enough to power the entire U.S. five times over.

The Justice for Breonna Taylor Act was introduced in the Senate banning No Knock Warrants nationwide

A bill was introduced in the House requiring the US Postal Service to cover the costs of any laid fees on bills the USPS failed to deliver on time

The Senate Confirmed 3 more Biden nominees to be life time federal Judges, Jasmine Yoon the first Asian-America federal judge in Virginia, Sunil Harjani in Illinois, and Melissa DuBose the first LGBTQ and first person of color to serve as a federal judge in Rhode Island. This brings the total number of Biden judges to 185

midnight, eventually? 𐙚 dean winchester

dean winchester x gn!reader

tags and warnings: early season fluid (or pre season 1 if you squint) alcohol consumption, dean's touch starved is showing, kissing (no smut), dean needing to feel normal for once. fluff! little angst. (I hate you john winchester)

summary: it's new years eve and Dean decides to accompany you to a party he wasn't invited too.

The elevator felt slower than it had ever been.

So much for new beginnings? You thought. You were dressed like you actually cared about the countdown, the dramatic ball drop, the shouting, the false hope that eventually sinks into crushing realization about mid June. But you played along, outfit clinging to the brash optimism you tried on for the night.

The elevator, your worst enemy, lurches at floor three and in he steps. Tall, tired, wearing a worn leather jacket like it's armor. His eyes find you instantly. Green, verdant.

Sharpened by something weathered and weary. And you? You blink at him like he's a mirage in the middle of the desert. "Bringing in the new year with whiskey? Not even a tequila soda?" You joked before your brain could stop you.

He huffs a laugh, "I don't do clear liquor before midnight."

"Two hours to go." You smile, and he mimics a toast. The liquid in the glass bottle he held sloshed. The silence that follows isn't awkward, it's charged with something. Like an old amplifier, waiting to catch sound. You're on your way to the twelfth floor, your friends probably four shots in of any alcohol they could find at the party while waiting for you.

"You've been condemned to the infamous new year's eve party too?" You nonchalantly ask as the elevator drags.

"Depends."

"On?" You reply. "You any good at small talk?" He lifts an eyebrow.

"Terrible."

He grins. "Sounds perfect. Dean."

"Y/N." She smile for the first time tonight.

You arrive together. The apartment was packed. Glitter-slick strangers, noise like broken glass, music rising to the ceiling. Champagne rivers and shuffling feet are interrupted by a girl in sequins. Her screams signal she's spotted you, an old friend, the condemner.

Dean lingers near the entrance, like the wolf at the edge of a territory that wasn't his own. You pull him in, refusing to go down alone.

He sticks close, not in a creepy way, more like gravity. You introduce him as a "friend from out of town" and he plays along. Instantly charming your friends with dry wit and boyish charm. He was a natural socializing.

Flirtatious banter with anyone who crossed his path, sending them swooning in their ongoing travels.

"Champagne," he said after a rough swallow. "Tastes like batteries and bad decisions."

You laughed.

"You're not from here," You said.

"Give it away that easily, huh?"

"It's the leather jacket." you teased.

The night carried on, the music slowed from the high pitched synched or club remixed pop music. It was something older, slower, dustier, a song made from nostalgia and smelled of cigarettes. He seemed to find comfort in it.

"Dance with me."

He blinked in disbelief. "What?"

"Come on!"

"Sweetheart," He said, lips tugging up, "I don't really-"

"Then let me lead."

That shut him up. You stepped closer. He hesitated, then gave in. Maybe just to see what you'd do. His hand found your waist, other taking yours with surprising care.

You fit together awkwardly at first, a little stiff, a little uncertain but you moved anyway.

And then, somewhere between the first step and the second breath, it clicked.

His fingers were calloused, but his grip was gentle. He smelled of leather warmed by the sun, after shave with a sharp edge and a whisper of caramel.

He looked at you like he didn't understand what was happening, but he didn't hate it.

You leaned in slightly. His arm tightened just enough to catch you.

"See," you murmured. "Not so bad."

He exhaled a laugh close to you, "yeah, yeah."

The song stretched on, and for him, it was a golden pocket of time where the world didn't need to be fixed, no one had to be saved.

You laid your head lightly against his shoulder, and he didn't pull away. He melted into you.

No words, just the sway of two people pretending for a night, that this could be something simple.

When the song ended, he didn't move right away. Neither did you. But then someone bumped into you, a girl laughing too loud, a guy with glitter riddled in his beard. The moment broke, reality leaking back in.

Dean cleared his throat, stepping back. You missed his shoulder immediately, and he missed your arms.

By 11:32pm you felt a hand at the small of your clothed back. A light touch, not possessive, just there, lingering. "You want out of here?" He asked low, against your ear.

You nodded.

The party faded behind you. He had found a solution, the roof, that neither of you should've had access too. But you didn't ask questions. The city stretched below, indifferent and alive.

He pulled a flask from his jacket, he had long abandoning the whisky bottle you met him with.

You took a sip. More whiskey.

"You always crash parties alone?" You ask, hiding your distaste in his choice of alcohol.

"I usually crash worse things."

"Like what?"

He gave you a look. Shrugging. "Let's just say, I've seen my fair share of bad nights."

He was silent, in thought. The city lights speaking for the two of you.

"You ever feel like you're living someone else's life?" He dryly spoke after another swig.

"All the time," you said.

He nodded, as if you'd just confirmed something for him.

The December winds picked up like if they were on cue, and he didn't hesitate to offer you his jacket once he noticed it had bothered you. "It's not a proposal. Just take it."

You did.

"Five minutes." He said, checking the time.

You laughed, "You keeping time now?"

"I got a thing for clocks."

You leaned against the railing, back towards the city, eyes center stage. "What happens when it hits midnight?"

He looked at you. For real. It was a heavy look. "Nothing," he said. "Unless you want it to."

You didn't mean to lean in. But you did.

And he didn't mean to meet you halfway. But he did.

The kiss was unscripted. No fireworks, no roar of the party, just a long pull of something aching. You tasted whiskey, a hint of danger, and every missed chance you didn't take before.

Then the countdown roared from below.

Ten..nine...

"You sure?" He pulled back, but not far.

You nodded.

Three...two..

He kissed you again. This time both hands at the small of your back. Your hands found themselves loosely behind his neck.

You craned upwards he met you at the small distance. The kiss began as if the two of you were unsure, but developed into something comforting. You melted at the warmth you sparked in him.

The two of you stood there together, your second chance of perfection a success. Colors blasted overhead, the city beneath seemed to cheer you on.

Dean however, worked as if it was silent. He led the kiss, your lips crashing into each other. He pulled you into his body as if he was afraid to let you go.

He seemed to find comfort in your arms even if it was brief, and you were strangers. He needed this.

But, he tore himself from you, his eyes fluttering open and once they had you could tell he yearned for more of you. But he resisted.

You stayed out there a bit longer after the party below had simmered to a hush.

Dean looked out at the skyline, closer to you than before. "I should get going."

You wanted to ask him to stay, but you didn't.

He didn't want to leave you, but he did.

The elevator carried you both back down to the first floor, you rode with him despite knowing you'd be going back up. There was a comforting silence, your fingers interlocked.

But once the doors of the elevator dragged open, he reluctantly released you from him. At first you didn't think he would turn around once he went forward.

Yet, as the view of his shoulders became bordered by the silver doors of the elevator, suddenly they parted once more. He gave you a smile, full of charm and something else.

He handed you a scrap of paper, a phone number. "If you ever find yourself on the road," he said. "Look for a '67 impala, black, no plates. I'll pull over."

And then he was gone.

Optimize your main batteries

Tigellinus folded his hands behind his back.

“All right, summarize the situation for me,” he said. “We’re nearly there, now tell me who we’re fighting.”

“Information is sparse, Grand Admiral,” his intelligence wonk said, apologetically. “According to the data burst we got from our informant, the shipyards on Cheres IV have been abnormally active for the last six months.”

“...and this concerns us?” the Grand Admiral asked.

“It does, Sir,” the intelligence officer replied… whatever his name was. Hernas, perhaps?

“While Cheres IV is primarily known as a freighter yard, they were involved in warship construction during the Clone Wars, and none of their manufacturing systems have been replaced. They have the smelters able to handle high powered weapons and the volume to produce capital ships.”

“A capital ship yard that we didn’t monitor?” Tignellius asked. “Who is supposed to be in charge of this Oversector, anyway? This is a clear and direct failure by someone. Make a note.”

“Yes, Admiral,” an aide said, tapping away at a datapad.

“As for this yard, hmm…” Tignellius frowned. “Why wasn’t it being monitored?”

“Every shipyard in the Empire could produce capital ships,” the intelligence officer pointed out. “Cheres IV is somewhat higher capacity than others, but it’s shown no hint of involvement until now. What actually raised my concern is not so much the report of high activity but that it’s dissonant with the other, pre-existing reports which were being sent by the management. Somebody is lying to us.”

He flicked to a new page. “According to our best estimates, the maximum possible construction volume they could have completed roughly amounts to a single Star Destroyer of the Imperial class, plus escorting cruisers in proportion. Rebel assets that could have been deployed to defend the yards might amount to as many as two of their capital ships, their Star Destroyer equivalents. Again, escorts in proportion.”

Tigellinus frowned, then nodded.

“It’s fortunate we have ten Star Destroyers in the core of our fleet, isn’t it?” he asked. “Still, we’d best not be too hasty… order to the fleet, all ships are to deploy their full complement of fighters as soon as we drop out of hyperspace. They are to form a screen; if the enemy launches a fighter strike, send out a combined interception force anchored on the Carracks to blunt it. I won’t take losses against a clearly inferior foe. We’ll offer them one chance to surrender to preserve the docks, then I’ll destroy whatever is there with turbolasers. Stormtroopers will convince the Cheresi board of directors of their folly.”

The ops personnel copied that down, converting it into orders, and Tigellinus looked up at the main viewscreen.

Not long now. And he’d show the rebel scum what the might of the Empire could do.

Starlines formed, then condensed into stars, and Tigellinus looked at the tactical display.

The whole formation was neat and ordered around his flagship, Praetor, and he allowed himself a moment of satisfaction.

“Report,” he snapped. “Get me targets!”

“Scanning now, Admiral!” someone called back. “Dropping the images on the plot!”

Markers appeared, and Tigellinus frowned – then relaxed.

A dozen fighters were out on a clear combat patrol, and even as he watched they reacted to his presence. There’d be more launching soon, but he could only see four of the Rebel light carriers – not enough to be a serious threat, not against the hundreds of TIEs his own force was sending into space, obedient to his orders and shaking out into combat formation.

But, more importantly, there were only two enemy heavy capital ships – not three. Both were consistent with Mon Cal designs, the damp aliens, though there were more light ships than he’d have expected.

“Have the Rebels really been building light ships here?” he asked, out loud. “Or have they been sending off what they build as soon as it’s complete… status on the Denier?”

“Interdiction cone coming online in sixty,” someone told him.

That, at least, was acceptable. He might lose the enemy cruisers, but the Mon Cal ships would be trapped before they could jump out and that was worth the entire trip.

“Admiral,” the intelligence officer said, appearing at his side. “I’ve been running the data streams, and there’s something wrong about the enemy combatants.”

“Then tell me what it is, Hernas,” Tigellinus said, shaking his head with a sigh. “Don’t play riddles with me. What are we facing?”

More fighters were appearing on the screen, and half his attention was on the body language of the two forces… would the Rebels try and launch a strike on Denier, hiding behind the body of his fleet? Run now with everything that could jump? Or try desperately to save the two Mon Cal Star Cruisers, opening themselves up to complete destruction?

“The cruisers don’t match anything that we recognize, but there’s at least a hundred of them,” Hernas said. “All built to the same design. And the Mon Cal cruisers have a different profile, it’s distorted along the dorsal and ventral lines.”

The big ships in question were neither turning to run nor turning to close the range, Tigellinus noted – or, at least, not by much. Instead they’d turned to fly left-to-right along his formation’s front. And the lighter cruisers were forming up into a clearly planned formation, with the Rebel fighters behind them on patrol.

What was going on?

“We’re in range of the cruisers, sir,” an ops officer said. “The Mon Cal ships are behind the enemy cruiser line, still.”

“Open fire on the cruisers,” Tigellinus replied. “Order the right wing to be ready to pursue those Star Cruisers – along with Denier. I want those prizes.”

“Yes, sir,” the ops officer replied, and the heavy turbolasers either side of his flagship’s main bridge turned, elevated – then fired. Nine other Star Destroyers fired in unison, spitting nearly a hundred and sixty coherent bolts of light out at the enemy cruiser line.

And about five hundred came back.

First Action, in the formation to the left of Praetor, staggered visibly as her shields took an intense hammer blow. Three of the enemy cruisers had taken multiple hits, one of them exploding as it was flattened in a single blow, but they were small targets and First Action was a massive target… one which had just taken so much concentrated energy that the shield systems were unable to fully contain it.

“What the kriff was that?” Tigellinus demanded.

“The cruisers!” Hernas warned. “Sir – they’re built around capital ship turrets!”

Turrets.

Turrets.

The produce of the damn shipyards hadn’t been sent away at all. It was right here. The heavy turbolaser turrets of an Imperial-class were a tiny fraction of the total volume, and the metal it took to build a single Star Destroyer could build hundreds of heavy turrets instead of the eight actually fitted to ships like his flagship.

First Action got hit by a second hammerblow of energy, crackling before a series of internal explosions began, and a moment later a priority alert came in from Interrex on the right wing of the formation.

The two Mon Cal Star Cruisers had been heavily refitted, Tigellinus realized in a sudden flash of insight. Their dorsal and ventral lines were nothing but turrets, with at least six times the heavy gun complement of a Star Destroyer – each – and that was if they hadn’t had heavy turrets added to the port and starboard sides, as well.

The Star Cruisers had his fleet outgunned. The enemy light cruisers, separately, had his fleet outgunned.

“Get us out of here!” he snapped. “Tell Denier to shut down her gravity well projectors!”

“They’ve only just come up, sir!” Hernas pointed out. “It’s going to take several minutes to-”

The entire ship rocked, as Rebel heavy turret fire marched down the formation, and Tignellius regretted his life choices.

Briefly.