Pyromedvediology: Unmasking the Great Deception That Became Truth

TWILIGHT OF THE LABORATORY
Bathed in the lab’s dusky glow, shimmering electronic displays mingled with the ghostly reflections of ancient scrolls, each dancing light hinting at a growing sense of foreboding. Just after Dr. Aurora Verlak finished logging the latest figures on a transparent screen, she felt a chill spread through her chest when, without warning, a loud crackling erupted from one of the sections—a piece of overheating apparatus throwing sparks like a mischievous electron gone rogue. (Someone joked that if the machine got any hotter, the research team might roast marshmallows for a midnight snack.)

MAIN PURPOSE OF THE RESEARCH
This narrative is primarily intended for graduate students in technical fields, as well as for curious readers who lack specialized scientific knowledge but yearn to understand the essence of modern investigation. The events described here matter deeply to these individuals because cutting-edge experiments—much like those happening in Dr. Verlak’s laboratory—may someday transform everyday life. From developing innovative devices to integrating pioneering technologies, they expand the boundaries of what we believe is possible and open up entirely new vistas for interpreting our world.
For example, harnessing these studies can speed up the analysis of vast data sets, reduce expenses in technical projects and industry, and apply an interdisciplinary approach more effectively when creating innovative solutions. One colleague even joked that if the data ran any faster, they would have to schedule coffee breaks in nanoseconds just to keep up. Indeed, anyone who takes advantage of these discoveries enjoys a distinct competitive edge, since a scientifically grounded method leads to more accurate decisions, higher reliability, and stronger reproducibility of results.

Her assistant, a young engineer named Leo, leaped to his feet, his eyes lit with alarm: 'Doctor, the system readings are unstable! It looks like the experiment is pushing beyond safe limits!' As though reminded of her mentor’s guidance while boldly challenging established procedures, Aurora scrutinized the shimmering lines of the graphs, as if they were mirrors of her own inner struggle. Recall how her mentor once said, 'Innovation without limits is destined to repeat old mistakes in new guises.' Now each pulsing change in the system echoed those words.

In a domain where ancient knowledge meets state-of-the-art technology, a new drama was emerging—a conflict between fear and the urge to unearth the unknown. Just as researchers merge and clash with their ideas on the path to discovery, the entire lab team found itself at the brink of a decision where even the smallest detail could prove critical. One colleague solemnly noted that 'most problems worthy of the name carry at least one fundamental conflict'—an important reminder that can banish fear and open the way to fresh perspectives, provided that courage overcomes doubt.
Aurora took a deep breath, realizing that this very conflict might spark a genuine breakthrough. The team began to regroup: some members argued for an immediate halt to the experiment, while others—resembling explorers searching for the unknown—insisted that examining the malfunction signals in detail could radically reshape established approaches and lay the foundation for groundbreaking discoveries. Tensions rose, yet instead of mere distrust, they signaled a chance for deeper analysis that could transform what seemed like a catastrophe into a bold creative challenge.

IMPORTANCE OF THE SITUATION FOR THE NEXT GENERATION OF ENGINEERS
It is especially important for future engineers and scientists to recognize how these kinds of instabilities during research highlight the razor-thin boundary between familiar methods and trailblazing ideas. Understanding these contradictions provides valuable preparation for tackling unconventional real-life problems and broadens one’s perspective, allowing the seeds of new insights to sprout among the ruins of outdated theories. (One of the lab technicians even joked that if their calculations got any riskier, they’d have to issue hard hats just to open a spreadsheet!)
Aurora took a long, steady breath, sensing that this very clash of ideas might trigger a profound breakthrough. The team regrouped with divided opinions: some called for an immediate halt to the experiment, while others—like adventurers on the brink of a new frontier—urged everyone to scrutinize the malfunction signals in meticulous detail. They believed a deep dive into the glitches could shake up conventional methods and pave the way for astonishing discoveries. Emotions ran high, but rather than fostering distrust, the tension sparked a chance for deeper insight—a moment to transform what looked like a catastrophe into a daring creative challenge.

It is especially crucial for aspiring engineers and scientists to observe how such research instability exposes the fine line between tried-and-true practices and fearless innovation. Recognizing these contradictions helps one prepare for unexpected real-world problems and broadens the capacity to plant new insights where outdated theories once stood. (One of the lab technicians even joked that if their calculations got any riskier, they would have to issue hard hats just to open a spreadsheet!)

• It offers a clear way to feel the contrast between proven and bold methods, highlighting how to roll out fresh technologies more effectively.
• It enhances data analysis skills whenever events take an unforeseen turn, which can speed up the discovery and handling of unconventional solutions in both industry and IT.
• It demonstrates how conflict can spark change and fresh approaches, encouraging better planning for large-scale projects and reducing risks during implementation.

(Another team member added a cheeky remark that if the meltdown alarms kept blaring like this, they might need to install a donut dispenser next to every red warning light—because who wouldn’t want a sugar fix while wrestling with urgent equations?)

Meanwhile, the flickering instrument lights switched faster and faster from soft glows to flashing red warnings, plunging the lab into a tangible sense of uncertainty. Dr. Verlak, holding an ancient parchment with ancestral writings, quietly observed, ‘Every conflict holds the spark of transformation.’ As she looked up at the tense but determined faces of her fellow researchers, she felt that in this whirlwind of opposing viewpoints, genuine science was taking shape—uniting age-old traditions with daring dreams of what the future might become.
WHEN NATURE AND TECHNOLOGY COLLIDE AT THE POINT OF TENSION

Beneath the shivering glow of laboratory instruments and ancient manuscripts—where every flicker of an electronic display mirrored both hope and doubt—the research team pressed on with their kaleidoscopic data analysis. In the corner of the lab dedicated to observing incredible natural phenomena, from the puzzling feeding habits of lampreys to the synchronized behavior of insects and the remarkable tensile strength of spider silk, the tension reached a critical high. Jagged lines on the transparent screen suddenly took on new, unsettling hues, hinting at elusive discrepancies that could topple established theories.

Dr. Harriet Aiven, her eyes lit by visionary ideas and unwavering belief in the revolutionary power of discovery, was the first to suggest a risky, never-before-seen method for rapid data processing. Her voice—firm and resolute—cut through the rumble of overworked systems and the flicker of overhead fluorescent lights, making it feel as though reality itself quivered at the threshold of this new step. In response, Dr. Marcel Tan, visibly anxious about a potential breakdown, declared loudly, “We can’t just smash through the boundaries of tradition without weighing the consequences! Every innovation needs a foundation in proven principles, or we’ll lose the ability to explain even the simplest phenomena.”

(One junior researcher couldn’t help joking that if these lampreys ever got ahold of the lab’s half-glitched data, they would probably swallow it whole—faster than any algorithm could ever process it.)
While the two scientists’ arguments merged with the soft hum of the equipment, Dr. Aurora Verlac—antique parchment in hand, rich with ancestral wisdom—kept a keen eye on the interplay between the instruments’ responses and the team’s inner tensions. Her gaze, reflecting both the turbulence of her private thoughts and the depth of her scientific insight, searched for equilibrium between bold new ideas and the caution demanded by truth. Echoes of her mentor’s parting words lingered in her mind, reminding her that every conflict holds the seed of transformation. Those words reverberated through the subdued stillness of the laboratory, where the glowing lights of the instruments seemed to highlight the risks born of audacious ambition.

Unseen patterns in the data began to surpass traditional limits, their cryptic signals reminding everyone that nature, like an ancient manuscript, forever guards secrets revealed only to those who dare to look beyond the familiar. Hushed whispers from tangled wires and the rumble of unpredictable experiments filled the air, as the team—torn between the desire for a breakthrough and the fear of reckless abandon—felt tensions mount with every heartbeat, drawing them ever closer to that fragile edge between inventive brilliance and irreparable catastrophe.
In the tense atmosphere, where every flicker on the screen reflected both hopes and fears, Harriet and Marcel persisted in their debate, their voices merging into the laboratory’s symphony of soft beeps and hisses. Beneath the glow of fluorescent lamps, Verlac’s quiet yet resolute voice was heard: 'Dear colleagues, let us not allow our hearts to eclipse the light of reason. Only by pairing the courage of innovation with the wisdom of tradition can we uncover the truth hidden within these data.' Like a tuning fork, those words briefly calmed the passions in the room, sparking hope that the clash between daring risk and careful restraint might become a catalyst for astounding discoveries.

In this vortex of paradoxes and experiments, where scientific principles entwined with bold aspirations, the team gradually came closer to unraveling what once seemed an enigma. Each flickering signal, each hiss from the overheating instruments, each flash of unruly data carried the potential to upend familiar notions of the world. Despite all the contradictions, it was precisely this precarious dance between the unknown and hard-earned experience that promised to guide them toward a breakthrough, granting shape to the future of science. At one point, Harriet glanced at the newest data spike and dryly remarked, 'If these readings keep climbing, we’ll need a whole new type of safety goggles just for our eyebrows.' Even amid the tension, a faint ripple of laughter passed through the lab, reminding everyone that sometimes the best antidote to the unknown is a well-placed joke.

NIGHTTIME DISCUSSIONS AND AN UNEXPECTED REVELATION
Late at night, when lightning flickered beyond the windows and the distant rumble of thunder echoed like some primordial beast, the laboratory turned into a place of confessions. In the half-light of dusk, where every glow of the instruments seemed to resonate with hidden mysteries, Dr. Verlac quietly confided in Dr. Tan. Her voice was scarcely more than a whisper, barely rising above the soft roar of the machinery.

'What if our boldness—our daring steps into the unknown—ends up laying the groundwork for destroying everything we’ve labored so long to achieve?' she asked, her gaze filled with both passion and doubt, like a flame dancing on the edge of a chasm.

Dr. Tan, normally composed and steadfast, stood frozen for a moment, plunged into the depths of unspoken ambition. His words emerged slowly, as though they were timid about revealing themselves in this private exchange.
Each surge of innovation, he said, is born of necessity, yet I cannot shake the feeling that we tread a fragile line—balanced precariously between groundbreaking discoveries and the unraveling of the old order.

In that quiet moment, as the laboratory lamps cast flickering shadows like living silhouettes plucked from ancient myths, both scientists felt time’s pulse slow almost to a standstill. Behind them, amid the hum of overheating systems and the faint whisper from tangled wires, something astonishing was taking shape. He managed a wry grin and added, “At least it can’t be worse than the day we short-circuited half the lab, turning the floor into an impromptu disco party. One dancing fiasco was enough for me.”
At the center of the experimental setup—where it was once considered impossible to disentangle what seemed forever bound—scientists blended intuition with time-tested principles. Then, as if someone had pressed slow-motion on reality, the instruments in the lab unleashed a blinding radiance. Fire, neatly lifted away from heat, swept across the monitor like sparks from a primordial force, while light, now freed from its usual thermal confines, draped the room in a hushed, electric thrill.

For those just beginning their journey in research, moments like these show that the most daring ideas can do more than spark our imagination—they can usher us straight to the edge of bold discovery. And yet, it is exactly such revelations that often become the bedrock of breakthrough technologies, broadening our understanding in ways that ripple through countless fields, from medicine to energy. These insights help plan tighter-knit experiments, preserve resources and time for complex projects, and establish a launchpad for future scientific endeavors. (By the way, rumor has it the team’s next attempt involves separating caffeine from coffee—though the last time someone tried that, half the crew dozed off before the results came in.)

Every gaze turned to this transcendent display: rays of light, like strands of destiny, dancing along the walls, stretching into elongated, almost mystical forms that mirrored the combined tension and exhilaration of a collective creative surge. In that breathless instant, each heartbeat sounded loud and clear, echoing through the machine’s low hum—an unspoken reminder that the boundary between established wisdom and a touch of outrageous genius can be both astonishingly thin and immeasurably vast.
Dr. Verlak, eyes locked upon the unknowing infinity of those shifting hues, spoke in a quiet tone:

“In this celebration of light and emptiness, we return to the very cradle of scientific exploration. There, beneath the crackle of lightning and the whispered ancient laws of nature, the future is born.”

(And rumor has it that, once they master this dance of sparks and silence, they’re planning to isolate caffeine from coffee again. Let’s just hope they don’t lose half the team to nap time before the experiment’s done.)
In that precise moment, when the old dogmas fell to dust and left behind nothing but a shining aura of newness, the team grasped that a risk shaped from genuine doubts and bold ambitions could become the next bedrock of understanding. Amid flickering shadows and dazzling bursts of endless light, they ventured together into uncharted territory, where each discovery resounded as an anthem to life, and every innovation embodied that steadfast force carrying humanity through the ages.

CREATING THE FOUNDATIONS FOR A LEAP INTO THE FUTURE
Suspended in this instant, Dr. Verlak stood at the central console, her hands barely containing a swirl of relief and awe. The look she shared with Dr. Tan revealed that behind their achievement lay not only triumph but a razor-thin line of risk, one strong enough to sweep away all they had painstakingly built. Above them, the apparatus droned once more—like the laboratory itself, awakened by newfound energy and eager to prove that the breakthrough was more than just a dream.
(And rumor has it they’re about to extract caffeine from coffee in a novel way. Fingers crossed they don’t end up converting the entire lab into a giant espresso machine… though it might speed up those late-night calculations.)
Focusing intently, Dr. Verlak meticulously combined once-separate elements, channeling their energies into a shimmering accord. In her mind, flashes of ancient teachings mingled with the turbulent currents of her own experiences. She recalled the stern words of her mentor, yet also felt a deep inner certainty that science was now venturing onto an uncharted path where every step exacted a price. In a whisper, she repeated to herself, “We did it, but now we must prove it—and prove it worthy of trust,” treating those words like a solemn promise to the future.

A fresh surge of energy coursed through the room: the eyes of her colleagues, lingering in the half-light, gleamed with the shared realization that their success had forever altered the boundaries of scientific possibility. For Verlak, this breakthrough was more than an engineering triumph; it was also a reconciliation with herself—an instant when her greatest fears and most cherished hopes blended into a calm, unshakeable conviction. A quiet yet powerful echo of past generations stirred in her heart, warning of the world’s fragility and, at the same time, inspiring bold yet measured steps onward.

Slowly but surely, everyone began gathering the experiment’s data—results that exceeded their hopes but demanded further scrutiny. Each flicker of the instrument’s light and each flash of energy quickened their pulses, a vivid reminder that science is not mere faultless logic. It is also a dynamic current of creative passion and an unrelenting quest for truth.

(And in the spirit of forging bold frontiers, there’s a rumor they might adapt part of this energy-harnessing technique for a coffee-fueled lab station. But let’s hope they don’t end up engineering a mega-espresso machine—though, on second thought, it could certainly perk up those late-night data-crunching sessions!)
Dr. Tan, maintaining his characteristic inner resolve, quietly remarked: 'Our approach today proves that true discovery arises from unwavering dedication and a profound respect for those who came before us. Yet our innovation must be shaped into a reliable form, or we may lose everything.' His words, steeped in stern wisdom, found an echo in every heart gathered there.

At that very moment, as laboratory instruments lit up once again with vivid hues, the team—united by the shared thrill of discovery—understood that science calls not only for courage and daring, but also for a tireless battle against one’s own doubts. For Dr. Verlak, it was more than an engineering achievement; it was the start of a journey toward a wiser, more purposeful future, where innovation and responsibility walk hand in hand, forging a bright new path through the boundless universe of knowledge.

And here’s a little lighthearted thought: if they ever succeed in channeling this remarkable breakthrough into powering the lab’s coffee maker, they just might brew a blend so potent that it finishes all their experiments before noon—provided the equipment doesn’t develop its own taste for coffee breaks.
At the moment the final data was recorded by the instruments, the atmosphere in the laboratory shifted from anxious anticipation to steadfast resolve. Dr. Verlak, sensing the pulse of a new phase, quietly said: 'We have taken a tremendous leap forward, but now it is time to combine bold ideas with the immortal wisdom of our predecessors.' Her words echoed through the chamber, a vivid reminder that every new innovation needs the support of solid foundations.

Dr. Tan, lifting his gaze slightly from the flickering screens, remarked: 'Our experiment has shown that true discovery emerges precisely when we integrate radical scientific concepts with well-established methods. Only then can we overcome contradictions, transforming them into a synergy where the collective effect far surpasses the sum of individual achievements.' His voice, weighted with sober insight, seemed to declare: 'Paradox forms the basis of progress. Every breakthrough carries a challenge, and every challenge is a chance to grow.'

In this decisive moment, an atmosphere of unity settled over the laboratory, as everyone present—from graduate students to lead researchers—realized their shared energy could elevate each individual’s efforts. It was like a finely tuned symphony of living organisms, embodying the principle of synergistic collaboration. One scientist's quote captured it perfectly: 'The core of the synergy principle is that the combined effect of interacting forces exceeds the sum of their separate influences.' This vision took bright form in the blending of tradition and innovation, forging fresh frontiers at the very edge of science.

And here’s a little jest inspired by their grand endeavor: if they ever focus all this synergistic power on the lab’s coffee maker, they might brew a paradoxically strong cup so advanced it could start writing their research papers—though they would have to keep a watchful eye on its growing aspiration to be listed as co-author!
Seizing the powerful momentum of the moment, the team arrived at a collective decision: every experimental breakthrough had to be reinforced with reliable methods to move forward on the path of continued research. 'Our duty is to preserve faith in scientific truth, and for that reason, we must prove that even the boldest ideas can flourish in the fertile field of time-tested practices,' declared Dr. Verlak, her voice resonating with a confident devotion—and a profound understanding of the balance between innovation and experience.

Bathed in the soft glow of instruments and the warmth of shared aspirations, the laboratory transformed into a place where science and the art of synergy found their true expression. The final chord of that quiet yet powerful dialogue—between a belief in the unknown and reverence for the past—rang out like a pledge to the future: by integrating radical concepts with established methods, they were forging genuine progress. It was in this harmonious blending of contradictions that they uncovered a force capable of transforming science, offering not just new pinnacles but also the resilience essential for society’s trust. And as a playful aside, one researcher joked that if they pushed this synergy far enough, perhaps the lab’s equipment would become so adept that it could brew a cup of coffee sturdy enough to support the weight of their most ambitious theories—yet refined enough to earn an honorary mention in their next publication.
REFLECTION ON THE RESULTS ACHIEVED

In the days that followed, the laboratory seemed imbued with an almost sacred atmosphere. At the final round table, all members of the team gathered to put the depth of their shared experience into words and to grasp the significance of their accomplishment. From young graduate students to wise veterans of science, everyone offered candid reflections: some spoke of crystal-clear moments of doubt, others of a reverent awe at the vastness of discovery, and many expressed deep respect for the delicate interweaving of groundbreaking ideas with time-tested methods.

Dr. Tan, with his usual composure and clarity of thought, mentioned how paradoxes and contradictions became his personal springboard for seeking truth. Each mismatch, hint, or apparent error, he explained, is a reminder that science thrives on the constant struggle between chaos and order. His voice carried profound respect for the law of equilibrium, which he believed to be at the root of genuine transformation. His words lingered in the minds of his colleagues, inspiring them to reflect on the fine line progress must tread between innovation and devotion to tradition. One younger researcher even joked that if they ever deciphered the precise meeting point of chaos and order, they might finally have the recipe for a cosmic-strength coffee potent enough to fuel the next discovery, yet refined enough to earn its own footnote in their published works.
Meanwhile, Dr. Verlac sat quietly in the corner, bathed in the gentle glow of the instruments, carefully stringing line after line of notes in her work journal. Each entry held not only precise data but also philosophical musings: for her, the merging of a spark of scientific inspiration with time-honored principles was like a fragile dance along the border between the unknown chaos and the strict regulations of proven methods. On one page, she captured how analytical thinking can build a bridge between the ideals of the past and the yearning for the future: 'True discovery is born within that harmony where risk intertwines with caution, and boldness is paired with discipline.'

A hushed yet vibrant exchange of insights and glances set the tone around the round table. One of her colleagues quoted a well-known observation about how some scientists blaze like lightning, while others, much like Einstein and Faraday, make vast contributions across multiple fields. The notion resonated with all present, awakening in each a reflection on how true progress emerges only when a restless search for the new draws upon an inexhaustible well of experience. In the midst of lofty reflections, someone ventured a lighthearted comment: if they ever perfected that elusive marriage of chaos and order, they would brew a coffee so potent it could guide them through the next breakthrough without once violating the lab’s safety policies.

In the quiet, broken only by the gentle sound of pen against paper, Dr. Verlac allowed herself a momentary retreat into thought. She recognized, as science itself does, that progress demands the artful poise of standing at the frontier of risk and tradition—like steering a system in which each forward-driving force meets its matching counterbalance. Her inner monologue echoed her mentor's words: 'Only by controlling the equilibrium between propelling and restraining forces can we avoid both the crisis of overproduction and the stagnation of growth.' Accompanying these reflections was an invisible confidence that this very balance would become the bedrock for the achievements yet to come.
By the end of the meeting, each participant quietly left the hall, infused with the warmth of shared efforts and mutual trust. A thought lingered in their minds: they had forged something greater than just another breakthrough. It was a creation where courage and discipline intertwined in a single symphony, proving that even the boldest ideas can bloom in the fertile soil of time-tested principles. And as they stepped beyond that day’s experiments, their collective wisdom promised that genuine discovery is, above all, a path paved not only with fresh insights but also with enduring values that grant confidence in tomorrow.

FAREWELL SPEECH AND CALL TO ACTION

As evening settled in, the gentle gleam of the instruments still reflected off the spotless walls, and the group gathered in anticipation of Dr. Verlac’s final words. What they saw before them was more than a familiar laboratory space; it was an entire cosmos of ideas rooted in steadfast traditions and fueled by the vital spark of innovation. At last, Dr. Verlac rose, summoning the strength and knowledge gained through many years of research, and her calm yet determined voice cut through the stillness:

'Every step we take leads us toward uncharted territory, yet each stride also relies on the firm ground of what has already been proven. If we dare to balance these two forces—our inner drive to explore and our abiding respect for established methods—we can continue building a future brimming with promise. And speaking of balance, perhaps the secret to our next big revelation lies in perfecting that harmony between chaos and order… especially if it helps us brew a cup of coffee robust enough to power future experiments without risking a single safety violation!'

With those words, she affirmed the path they had traveled together and the journey yet to unfold, calling them all to press onward—even as they honored the principles that had guided them so far.
We must stay fearless in our pursuit of groundbreaking ideas and humble enough to remember the wisdom of those who came before us. Only by blending that spark of discovery with the steadfast stronghold of tradition can we construct something that will truly stand the test of time.

Those words, like a gentle summons, echoed through the hearts of everyone gathered. All eyes turned to Verlac, who, despite a seemingly fragile appearance, radiated an aura of strength and unwavering composure. In that moment, each scientist felt the mentor’s call awaken a renewed determination, urging them onward while never straying from the unshakable support of the past.

And for a dash of fun—since experiments thrive on balance—let’s remember: the best formula for bold innovations might just be equal parts courage, tradition, and a coffee blend potent enough to spark genius without setting off any safety alarms!
At the table, sparks of unity among minds and hearts glimmered before our very eyes. Young graduate students, once weighed down by uncertainty, now found renewed confidence in the call to action. Seasoned veterans of science, fortified by years of dedicated research, fondly recalled the guidance of their own teachers, their gazes reflecting a profound belief in the power of balance between boldness and wisdom.

One colleague, speaking quietly yet with unmistakable resolve, remarked that they had listened, reflected, and now the moment had come to act. After all, freedom and the true might of knowledge lie in the ability to bravely take on challenges while still holding fast to principles proven by time. Those words, like an echo, resonated with the essence of an idea that genuine progress does not shun the past but transforms it into a tool for future triumphs.

A gentle breeze drifted through the open laboratory windows, a living symbol of change that reminded everyone how stepping beyond one’s comfort zone carries not only uncertainty but an endless expanse of possibility. Dr. Verlac took in the scene once more, her eyes alight with sincere conviction, declaring that fearlessness is not the absence of fear but the capability to move forward in spite of it. Their journey, she hinted, is guided not only by the brilliant glow of scientific inquiry but also by the deep wisdom that can guide them through any storm.

And in the midst of that earnest atmosphere, someone jested that the trickiest project of all might be brewing a coffee potent enough to fuel fearless innovation without setting off the lab’s safety alarms—a fitting reminder that a touch of humor can spark just as much progress as any bold experiment.
On this evening, the collective consciousness overflowed with determination and inspiration. Everyone stepping away from the muse’s circle felt like a participant in a grand voyage, where courage and humility, risk and discipline, intertwined in a single symphony of discovery. In precisely this way—through preserving the wisdom of the past and tirelessly reaching for the new—a fresh chapter began to unfold in the annals of science, promising not just technical breakthroughs but also a chance for personal growth in a world where each idea becomes a bridge between eternity and the perpetual quest for truth.

By the end of the night, someone joked that the real challenge was engineering a coffee so timeless it could fuel their entire journey without ever growing cold—though, they teased, the lab might need a special permit for that kind of perpetual innovation.