- Frequency falters after phase 2 fail, axing 2 assets and 55% of staff FierceBiotech
- Lexington biotech lays off half of its workforce after hearing loss drug fails major study The Boston Globe
- Biotech layoffs 2023: Frequency Therapeutics to lay off most of its staff in wake of trial failure – Boston Business Journal The Business Journals
- Frequency stock crashes 75% on cutting hearing loss programs as trial fails; cuts 55% jobs Seeking Alpha
- Frequency Therapeutics President, CEO Lucchino Takes Medical Leave >FREQ MarketWatch
- View Full Coverage on Google News
Tag Archives: frequency
Frequency Therapeutics reports trial fail and lays off over half of staff — stock capsizes – Endpoints News
- Frequency Therapeutics reports trial fail and lays off over half of staff — stock capsizes Endpoints News
- Frequency falters after phase 2 fail, axing 2 assets and 55% of staff FierceBiotech
- Frequency stock crashes 75% on cutting hearing loss programs as trial fails; cuts 55% jobs Seeking Alpha
- Biotech layoffs 2023: Frequency Therapeutics to lay off most of its staff in wake of trial failure – Boston Business Journal The Business Journals
- Frequency Therapeutics President, CEO Lucchino Takes Medical Leave >FREQ MarketWatch
- View Full Coverage on Google News
Frequency Therapeutics Announces Topline Results for its Phase 2b Study of FX-322 for the Treatment of Sensorineural Hearing Loss – Yahoo Finance
- Frequency Therapeutics Announces Topline Results for its Phase 2b Study of FX-322 for the Treatment of Sensorineural Hearing Loss Yahoo Finance
- Frequency falters after phase 2 fail, axing 2 assets and 55% of staff FierceBiotech
- Biotech layoffs 2023: Frequency Therapeutics to lay off most of its staff in wake of trial failure – Boston Business Journal The Business Journals
- Frequency stock crashes 75% on cutting hearing loss programs as trial fails; cuts 55% jobs Seeking Alpha
- Frequency Therapeutics President, CEO Lucchino Takes Medical Leave >FREQ MarketWatch
- View Full Coverage on Google News
High Frequency Brain Wave Patterns in the Motor Cortex Can Predict an Upcoming Movement
Summary: Spatially organized recruitment of neural activity across the motor cortex informs details of planned movements.
Source: University of Chicago
Nicholas G. Hatsopoulos, PhD, Professor of Organismal Biology and Anatomy at the University of Chicago, has long been interested in space. Specifically, the physical space occupied by the brain.
“Inside our heads, the brain is all crumpled up. If you flattened out the human cortex into a single 2D sheet, it would cover two and a half square feet of space — roughly the size of four pieces of paper. You would think that the brain would take advantage of all that space when organizing activity patterns, but aside from knowing that one patch of the brain controls the arm and another controls the leg, we’ve mostly ignored how the brain might use that spatial organization.”
Now in a new study published on January 16 in Proceedings of the National Academy of Sciences, Hatsopoulos and his team have found evidence that the brain does indeed use the spatial organization of high frequency propagating waves of neuronal activity during movement.
The presences of propagating waves of neuronal activity has been well-established, but they are traditionally associated with the general behavioral state of an animal (such as awake or asleep). This study is the first evidence that spatially organized recruitment of neuronal activity across the motor cortex can inform details of a planned movement.
The team hopes the work will help inform how researchers and engineers decode motor information to build better brain-machine interfaces.
To conduct the study, the researchers recorded the activity from multielectrode arrays implanted in the primary motor cortex of macaque monkeys while the monkeys did a task that required them to move a joystick. Then, they looked for wave-like patterns of activity, specifically those of high-amplitude.
“We focused on the high frequency band signals given its rich information, ideal spatial reach and easiness of obtaining signal in every electrode,” said Wei Liang, first author on the study and a graduate student in the Hatsopoulos lab.
They found that these propagating waves, comprised of the activity of hundreds of neurons, traveled in different directions across the cortical surface based on which direction the monkey pushed the joystick.
“It’s like a series of dominoes falling,” said Hatsopoulos. “All of the wave patterning we’ve seen in the past didn’t tell us what the animal was doing, it would just happen. This is very exciting because now we’re looking at this propagating wave pattern and shown that the direction the wave goes tells you something about what the animal is about to do.”
The results provide a new way of looking at cortical function. “This shows that space does matter,” Hatsopoulos said. “Instead of just looking at what populations of neurons do and care about, we’re seeing that there is spatially organized patterning that carries information. This is a very different way of thinking about things.”
The research was challenging due to the fact that they were studying the activity patterns from individual movements, rather than averaging the recordings over repeated trials, which can be quite noisy. The team was able to develop a computational method for cleaning up the data to provide clarity on the signals being recorded without losing important information.
“If you average across trials, you miss information,” said Hatsopoulos. “If we want to implement this system as part of a brain-machine interface, we can’t be averaging trials — your decoder has to do it on the fly, as the movement is happening, for the system to work effectively.”
Knowing that these waves contain information about movement opens the door to a new dimension of understanding how the brain moves the body, which can in turn provide additional information for the computational systems that will drive the brain-machine interfaces of the future.
“The spatial dimension has been mostly ignored thus far, but it’s a new angle we can use for understanding cortical function,” said Hatsopoulos. “When we try to understand the computations the cortex is doing, we should consider how the neurons are spatially laid out.”
Future studies will examine whether similar wave patterns are seen in more complicated movements, such as sequential movements as opposed to simple point-to-point reaching, and whether or not wave-like electrical stimulation of the brain can bias the monkey’s movement.
Funding: The study, “Propagating spatiotemporal activity patterns across macaque motor cortex carry kinematic information,” was supported by the National Institutes of Health (R01 NS111982). Additional authors include Karthikeyan Balasubramanianb and Vasileios Papadourakis of the University of Chicago.
See also
About this movement and neuroscience research news
Author: Alison Caldwell
Source: University of Chicago
Contact: Alison Caldwell – University of Chicago
Image: The image is in the public domain
Original Research: Open access.
“Propagating spatiotemporal activity patterns across macaque motor cortex carry kinematic information” by Wei Liang et al. PNAS
Abstract
Propagating spatiotemporal activity patterns across macaque motor cortex carry kinematic information
Propagating spatiotemporal neural patterns are widely evident across sensory, motor, and association cortical areas. However, it remains unclear whether any characteristics of neural propagation carry information about specific behavioral details.
Here, we provide the first evidence for a link between the direction of cortical propagation and specific behavioral features of an upcoming movement on a trial-by-trial basis.
We recorded local field potentials (LFPs) from multielectrode arrays implanted in the primary motor cortex of two rhesus macaque monkeys while they performed a 2D reach task. Propagating patterns were extracted from the information-rich high-gamma band (200 to 400 Hz) envelopes in the LFP amplitude.
We found that the exact direction of propagating patterns varied systematically according to initial movement direction, enabling kinematic predictions.
Furthermore, characteristics of these propagation patterns provided additional predictive capability beyond the LFP amplitude themselves, which suggests the value of including mesoscopic spatiotemporal characteristics in refining brain–machine interfaces.
AMD Ryzen 7000 CPU Undervolting Can Leave A Lot of Frequency & TDP Headroom, Also Drops Temps Signficantly
Yesterday, we reported that AMD’s Ryzen 7000 CPUs would be really toasty when running at stock settings but don’t worry, Undervolting is there to save the day.
AMD’s Ryzen 7000 Desktop CPU Undervolting Could Offer Significant Frequency & TDP Headroom While Dropping Down Temps
In the previous report, we stated how AMD’s Ryzen 7000 CPUs have been alleged to run really hot even at stock TDP ratings. The Ryzen 9 7950X with a PPT of 230W and the Ryzen 5 7600X with a PPT of close to 130W are said to hit 90-95C temperatures at stock configurations which is almost at the edge of their thermal threshold. After hitting this threshold, the CPU will downclock itself and run at much lower frequencies of 5.0 GHz, a drop of -700 MHz.
If set manual V with same CLK, can get MUCH reasonable result. And there is a lot of CLK/temp headroom.
More than 3 weeks for launch. Wait and hope to fix this.
Many thanks for tip! ☺️
(2/2)
— 포시포시 (@harukaze5719) September 1, 2022
Now Harukaze5719 has found out to AIDA64 entries which are allegedly from an AMD Ryzen 5 7600X CPU. The first result shows us the stock configuration where the ES chip is seen running at a frequency of 5.05 GHz. The temperature can be seen sitting at 93.1C at 122W in the AIDA64 FPU stress test. This is a really high temperature but in the second window, we can see a manual Vcore adjustment which drops the temperature significantly down to 56.5C and also the wattage to just 68 Watts while retaining the 5.05 GHz.
It is likely that there could be a power or voltage bug in the AMD Ryzen 7000 ES/QS parts which is leading to such high temperatures but undevolting more or less fixes the issue. Now it remains to be seen whether the manually adjust voltage will be good enough to handle the 5.5-5.7 GHz clock speeds that the Ryzen 7000 CPUs have to offer. It could be possible that the undervolting is good enough for a 5 GHz clock speed but more voltage would be required to hit the higher frequencies.
Considering that the Zen 4 chiplets are smaller than their predecessor but much denser, they will require a lot of cooling. It looks like that might be one reason why the chiplets are also gold-plated this time to effectively move as much heat away from them and to the IHS. A new screenshot by leaker, Enthusiast Citizen, reaffirms his claim though once again, the result is based on an ES chip and the problem may have been tweaked in the final silicon:
All of this means that users should definitely look forward to investing in some really high-end AIO coolers if they plan on building a new PC with AMD’s Ryzen 7000 Desktop CPUs. Of course, this is just a rumor for now and we will wait for final tests and reviews to confirm the validity of this rumor but AMD has put in their best efforts to make sure that heat is dissipated off the CPUs by issuing a gold plating on both the IHS and the Zen 4 CCDs as detailed here. The AMD Ryzen 7000 CPUs launch alongside the AM5 platform on the 27th of September.
Which AMD Ryzen 7000 Desktop CPUs are you most interested in?Poll Options are limited because JavaScript is disabled in your browser.
AMD Ryzen 7000 ‘Raphael’ CPUs Allegedly Have A Maximum Frequency Limit of 5.85 GHz
AMD Ryzen 7000 Desktop CPUs have so far shown up with pretty insane frequencies, clocking as far as 5.5 GHz on multiple threads. But it looks like the final revision might offer even higher CPU clocks as reported by Angstronomics.
AMD Ryzen 7000 ‘Raphael’ Desktop CPUs Allegedly Have A Maximum Frequency Limit ‘Fmax’ of 5.85 GHz
Earlier this week, AMD corrected and confirmed a few more details regarding its Ryzen 7000 CPU lineup, codenamed Raphael. The company confirmed that the TDP of its top Ryzen 7000 CPUs will indeed be 170W and the maximum package power of the AM5 (LGA 1718) socket will be rated at 230W. The company also confirmed that the gaming demo showcased during Computex 2022 was of a 16-core prototype that was running at 5.5 GHz across multiple threads. But the company also, most importantly, confirmed that the prototype was running at an operating range below the new 170W TDP spec.
The Computex processor was a 16-core prototype sample not yet fused to specific power/TDP values, but it was operating in a range below the new 170W TDP group we’ve developed. It’s a conservative figure.
Robert Hallock at Reddit
So we know that AMD Ryzen 7000 Computex 2022 demo was not a single-thread clock speed showcase and it wasn’t even a final prototype that was utilizing the full 170W TDP spec. Now based on a report from Angstronomics’s sources, it looks like there exists an SKU (or an OPN) which is fused with a 5.85 GHz Fmax or maximum frequency limit.
Regarding frequency targets, the game demo showing 5.55GHz maximum frequencies was also not with the final version. While Angstronomics is aware of an Ordering Part Number (OPN) that is fused for a 5.85 GHz Fmax, we will have to wait and see what the retail stepping fuses will be set at.
via Angstronomics
5.85 GHz is an insane clock but considering that we only saw the first look at a prototype AMD Ryzen 7000 Desktop CPU, the final spec may very well be within this range. A 16-core part that utilizes the full 170 Watts available to it might just be able to exceed past the 5.5 GHz clocks & deliver clock speeds that we have never seen before on an AMD Ryzen CPU. Intel is also aiming for similar clocks with its Raptor Lake-S Desktop CPUs so it makes sense for AMD to go head-on head with the blue team in the clocks department, somewhere where they have lagged behind over the last couple of years.
We are already excited to see 5.5 GHz clocks for AMD Ryzen 7000 Desktop CPUs so anything above would be a treat for consumers who are looking forward to building a brand new AM5 PC with the latest Zen 4 powered Ryzen 7000 Desktop CPUs. Of course, such frequencies may only be allowed on the highest spectrum of AM5 motherboards such as the ones based on the X670E chipset with loads of VRMs to handle the power delivery requirements for the new Fmax spec.
Intel Raptor Lake vs AMD Raphael Desktop CPUs Comparison ‘Expected’
| CPU Family | AMD Raphael (RPL-X) | Intel Raptor Lake (RPL-S) |
|---|---|---|
| Process Node | TSMC 5nm | Intel 7 |
| Architecture | Zen 4 (Chiplet) | Raptor Cove (P-Core) Gracemont (E-Core) |
| Cores / Threads | Up To 16/32 | Up To 24/32 |
| Total L3 Cache | 64 MB | 36 MB |
| Total L2 Cache | 16 MB | 32 MB |
| Total Cache | 80 MB | 68 MB |
| Max Clocks (1T) | ~5.8 GHz | ~5.8 GHz |
| Memory Support | DDR5 | DDR5/DDR4 |
| Memory Channels | 2 Channel (2DPC) | 2 Channel (2DPC) |
| Memory Speeds | DDR5-5600 | DDR5-5200 DDR4-3200 |
| Platform Support | 600-Series (X670E/X670/B650/A620) | 600-Series (Z690/H670/B650/H610) 700-Series (Z790/H770/B760) |
| PCIe Gen 5.0 | Both GPU & M.2 (Extreme chipsets only) | Both GPU & M.2 (700-Series only) |
| Integrated Graphics | AMD RDNA 2 | Intel Iris Xe |
| Socket | AM5 (LGA 1718) | LGA 1700/1800 |
| TDP (Max) | 170W (TDP) 230W (PPT) |
125W (PL1) 240W+ (PL2) |
| Launch | 2H 2022 | 2H 2022 |
News Source: @hjc4869
How Often Should You Feed Your Dog? Giant Study Reveals a Surprising Answer
Every dog is different, and depending on things like their breed, size, age, and health, their particular dietary requirements may also be different, including what you should feed them, and how much.
But what about how often? A new study that assessed over 10,000 dogs offers some startling insights into the apparent links between feeding frequency and canine health – and the key takeaway is definitely food for thought.
According to the research, adult dogs that are fed only once per day tend to score significantly better across several indicators of health, compared with dogs that are fed more often.
“Controlling for sex, age, breed, and other potential confounders, we found that dogs fed once daily rather than more frequently had lower mean scores on a cognitive dysfunction scale, and lower odds of having gastrointestinal, dental, orthopedic, kidney/urinary, and liver/pancreas disorders,” the research team, led by first author and canine health researcher Emily Bray from the University of Arizona, explains in the new paper.
The results are gleaned from data collected by a broad, ongoing canine health study called the Dog Aging Project.
While you shouldn’t rush out and change your feeding routine just yet, the findings suggest that the kinds of benefits seemingly delivered by time-restricted eating – mostly seen in laboratory experiments involving rodents to date – might also extend to companion dogs.
Not that the results aren’t something of a surprise – even for the scientists doing the research.
“We weren’t confident at all that we would see any differences in dogs’ health or cognition based on feeding frequency,” explained senior author and biostatistician Kathleen Kerr from the University of Washington, back when the preliminary results were announced in December.
“I think we would have been excited to see an association between feeding frequency and health in just one domain. I was surprised to see associations in so many domains.”
While a feeding frequency of one meal per day was linked with better outcomes for dogs in some areas, in other domains it wasn’t so clear. Measurements for disease risk in terms of cardiac, skin, and neurological health, as well as cancer incidence, didn’t show statistically significant effects.
Beyond that, the researchers acknowledge a number of limitations to bear in mind with their study. All the feeding data was self-reported by dog owners – meaning it’s subject to errors in their recollection and interpretation – and the study wasn’t able to tease apart the possible influence of caloric restriction (which wasn’t measured in the study) from feeding frequency.
Nonetheless, despite the limitations, the team says this is the largest study to date of feeding frequency conducted in companion dogs, and there’s clearly something going on here to suggest that feeding your dog only once per day is linked with certain benefits to their health.
As for what that is, exactly, it remains unknown, and the researchers emphasize that the results only show an association, and do not demonstrate causality – meaning we can’t conclude that lower frequency of feeding actually causes better health in dogs.
For example, there could be lots of reasons why dogs with worse health might be fed more frequently than healthy dogs (being fed extra meals to take medication, for example), as Bray points out.
Until much more is known about the underlying mechanisms for this apparent phenomenon – and subsequent research can somehow explain the results further – nobody should change how often they feed their dog based on this one study, the researchers say.
“However, if supported by future studies, it may be prudent to revisit the currently predominant recommendation that adult dogs be fed twice daily,” the team concludes.
“The rationale for twice-daily feeding in dogs is obscure… and our study suggests that more frequent feeding may, in fact, be suboptimal for several age-related health outcomes.”
The findings are reported in GeroScience.
Here’s Why Earthquakes’ ‘Four-Leaf Clover’ Shockwaves Are Dangerous Instead of Lucky
Geologists have measured a devastating ‘four-leaf clover’ pattern of earthquake shockwaves in greater detail than ever before – and the resulting findings could be crucial in making our buildings and cities more resistant to large quakes in the future.
This four-pronged pattern has been analyzed before, but never in as much depth as this. The team behind the new study is hoping that it might remove some of the mystery surrounding how earthquake shockwaves spread out across different frequencies.
Crucially, the cloverleaf shockwaves spread at low frequencies of under 10 hertz, a level of vibration that many buildings and structures are particularly vulnerable to.
The four-leaf clover pattern is visible at lower frequencies. (Trugman et al., Geophysical Research Letters, 2021)
“We find that at low frequencies, a simplified and widely used four-lobed model of earthquake ground motions does a good job describing the observed seismic wavefield,” write the researchers in their published paper.
“At higher frequencies, however, this four-lobed radiation pattern becomes less clear, deteriorating due to complexity in earthquake source processes and fault zone structure.”
The researchers looked at data from one of the densest seismic arrays on the planet: the LArge-n Seismic Survey in Oklahoma (LASSO), which is made up of 1,829 seismic sensors within an area of just 15 by 20 miles (25 by 32 kilometers).
LASSO was used to measure P-wave data from 24 small earthquakes across a period of 28 days in 2016, and it’s this data that the new study digs into. Having sensors so close to the epicenter of the quakes meant that patterns could be spotted before they smoothed out and evened off over greater distances.
By using algorithms to filter shockwaves by frequency, the four-leaf clover pattern emerged, but only at the lower frequencies. That might be because lower frequency seismic waves can bypass the jumble of broken rock found at earthquake faults, rather than being reflected and scattered in many different directions.
“What happens when you have an earthquake is that pieces of broken rock inside the fault zone start to move around like pinballs,” says geophysicist Victor Tsai, from Brown University in Rhode Island.
The earthquakes recorded by the LASSO array were relatively small – barely perceptible to the sensors – but the same patterns should be repeated across stronger quakes, the researchers predict. The next step is to put that to the test.
Ultimately, new data like this can make earthquake assessments and modeling more accurate. It shows that while people on the ground might experience a consistent level of shockwaves (the higher frequency ones), the buildings around them might be under a greater or lesser level of stress (the lower frequency shockwaves), depending on where they are in the four-leaf clover pattern.
While earthquake faults vary in terms of their age, their geological composition, and other factors, the underlying physics should be the same. The scientists are hoping to put together a catalog of earthquake zones, showing the faults with the most potential for dangerous seismic waves and resulting damage.
“What’s important in these results is that close to the source we’re seeing a variation in ground motion, and that’s not accounted for in any sort of hazard model,” says the study’s first author, earthquake geophysicist Daniel Trugman from the University of Texas at Austin.
The research has been published in Geophysical Research Letters.
Increased Global Flood Risk Due to Intense Frequency of Extreme Ice Melting in Greenland
Surface meltwater flowing towards the ocean through a channel in Greenland. Credit: Ian Joughin
Global warming has caused extreme ice melting events in Greenland to become more frequent and more intense over the past 40 years according to new research, raising sea levels and flood risk worldwide.
Over the past decade alone, 3.5 trillion tonnes of ice has melted from the surface of the island and flowed downhill into the ocean.
That’s enough melted ice to cover the entire UK with around 15 meters of meltwater, or cover the entire city of New York with around 4500 meters.
The new study, led by the University of Leeds, is the first to use satellite data to detect this phenomena – known as ice sheet runoff – from space.
The findings, published in Nature Communications, reveal that Greenland’s meltwater runoff has risen by 21% over the past four decades and has become 60% more erratic from one summer to the next.
Lead author Dr. Thomas Slater, a Research Fellow in the Centre for Polar Observation and Modelling at the University of Leeds said:
“As we’ve seen with other parts of the world, Greenland is also vulnerable to an increase in extreme weather events.
“As our climate warms, it’s reasonable to expect that the instances of extreme melting in Greenland will happen more often – observations such as these are an important step in helping us to improve climate models and better predict what will happen this century.”
The study, funded by the European Space Agency’s (ESA) as part of its Polar+ Surface Mass Balance Feasibility project, used measurements from the ESA’s CryoSat-2 satellite mission.
The research shows that over the past decade (2011 to 2020), increased meltwater runoff from Greenland raised the global sea level by one centimetre. One third of this total was produced in just two hot summers (2012 and 2019), when extreme weather led to record-breaking levels of ice melting not seen in the past 40 years.
Raised sea levels caused by ice melt heightens the risk of flooding for coastal communities worldwide and disrupts marine ecosystems in the Arctic Ocean that indigenous communities rely on for food.
It can also alter patterns of ocean and atmospheric circulation which affect weather conditions around the planet.
During the past decade, runoff from Greenland has averaged 357 billion tonnes per year, reaching a maximum of 527 billion tonnes of ice melt in 2012, when changes in atmospheric patterns caused unusually warm air to sit over much the ice sheet. This was more than twice the minimum runoff of 247 billion tonnes that occurred in 2017.
The changes are related to extreme weather events, such as heatwaves, which have become more frequent and are now a major cause of ice loss from Greenland because of the runoff they produce.
Dr. Slater said: “There are, however, reasons to be optimistic. We know that setting and meeting meaningful targets to cut emissions could reduce ice losses from Greenland by a factor of three, and there is still time to achieve this.”
These first observations of Greenland runoff from space can also be used to verify how climate models simulate ice sheet melting which, in turn, will allow improved predictions of how much Greenland will raise the global sea level in future as extreme weather events become more common.
Study co-author Dr. Amber Leeson, Senior Lecturer in Environmental Data Science at Lancaster University, said:
“Model estimates suggest that the Greenland ice sheet will contribute between about 3 and 23 cm to global sea level rise by 2100.
“This prediction has a wide range, in part because of uncertainties associated with simulating complex ice melt processes, including those associated with extreme weather. These new spaceborne estimates of runoff will help us to understand these complex ice melt processes better, improve our ability to model them, and thus enable us to refine our estimates of future sea level rise.”
Finally, the study shows that satellites are able to provide instant estimates of summer ice melting, which supports efforts to expand Greenland’s hydropower capacity and Europe’s ambition to launch the CRISTAL mission to succeed CryoSat-2.
ESA’s CryoSat mission manager, Tommaso Parrinello, said:
“Since it was launched over 11 years ago, CryoSat has yielded a wealth of information about our rapidly changing polar regions. This remarkable satellite remains key to scientific research and the indisputable facts, such as these findings on meltwater runoff, that are so critical to decision-making on the health of our planet.
“Looking further to the future, the Copernicus Sentinel Expansion mission CRISTAL will ensure that Earth’s vulnerable ice will be monitored in the coming decades. In the meantime, it is imperative that CryoSat remains in orbit for as long as possible to reduce the gap before these new Copernicus missions are operational.”
Reference: “Increased variability in Greenland Ice Sheet runoff from satellite observations” by Thomas Slater, Andrew Shepherd, Malcolm McMillan, Amber Leeson, Lin Gilbert, Alan Muir, Peter Kuipers Munneke, Brice Noël, Xavier Fettweis, Michiel van den Broeke and Kate Briggs, 1 November 2021, Nature Communications.
DOI: 10.1038/s41467-021-26229-4
Intel Maximum Turbo Frequency Profiles Offers Up To 36% Performance Improvement on Core i9-12900K Alder Lake CPU
Intel is splitting its TDP numbers into two new categories starting with 12th Gen Alder Lake CPUs, Processor Base Power (PBP), and Maximum Turbo Power (MTP).
Intel 12th Gen Alder Lake CPUs TDPs Now Defined As PBP PL1 & MTP PL2, Up To 38% Performance With MTP
The first category is the base TDP of what a CPU processes. Power Level 2 is described as when a CPU is pushed beyond its PBP and is typically caused by the long-term duration of use (also known as Tau of PL2 by vendors of motherboards). It’s also known as when a CPU is overclocked, a feature that enthusiasts tweak and tinker with to see the level they can stress a product before it is unable to work as intended. Because of the needs of those enthusiasts, vendors and manufacturers add that to the descriptions so that consumers have that information ahead of time.
Not only is TDP replaced by PBP, but PL2 is now considered the CPUs Maximum Turbo Power. These new terms are now seen on slides from Intel’s marketing information along with other official performance information. With this new nomenclature for CPUs, reviewers are now tasked with making sure to use the proper modes when comparing with alternate solutions, avoiding any confusion from the audience, causing certain CPUs that are high producers to be more favorable.
Twitter user @9550pro found a screenshot from Weibo user Wolfstame. Wolfstame happens to be the Gaming Desktop Product Planning Manager of Lenovo China. The user posted a chart showing the comparison of the new Alder Lake CPU lines in both PL1 and PL2 modes in a Cinebench test—more specifically, the R20 multi-thread benchmark. This information has since been removed from the original poster, possibly due to embargo reasons. What is shown is the level of performance that MTP modes give to all three of the new Intel 12th Gen Core K-series processors.
This information is the closest we have seen to accurate performance since prior to AMD and Microsoft’s L3 latency issues that were plaguing Ryzen CPUs using Windows 11.
- Intel Core i9-12900K: PL2 – 10180, PL1 – 7492, PL2/PL1 – 136%
- Intel Core i7-12700K: PL2 – 8677, PL1 – 6689, PL2/PL1 – 130%
- Intel Core i5-12600K: PL2 – 6551 , PL1 – 5953 , PL2/PL1 – 110%
When looking at these calculations, we can see that the Intel Core i5-12600K chipset bodes 10% increased performance with PL1=PL2 mode when compared to the standard settings. Intel’s Core i7-12700K CPU has 30% better performance, and the i9-12900K has a staggering 36% better performance when utilizing the MTP mode.
Intel’s newest CPUs are set to release on November 4th, but retailers have already started taking pre-orders last week. Recently, Newegg appeared to have shipped the CPUs prior to the actual embargo date, and they are probably not the only retailer that has made that mistake. Unfortunately, without access to the Z690 motherboard, the chips are unusable until those devices become available.
Intel 12th Gen Alder Lake Desktop CPU Specs “Rumored”
| CPU Name | P-Core Count | E-Core Count | Total Core / Thread | P-Core Base / Boost (Max) | P-Core Boost (All-Core) | E-Core Base / Boost | E-Core Boost (All-Core) | L3 Cache | TDP (PL1) | TDP (PL2) | Expected (MSRP) Price |
|---|---|---|---|---|---|---|---|---|---|---|---|
| Core i9-12900K | 8 | 8 | 16 / 24 | 3.2 / 5.3 GHz | 5.0 GHz (All Core) | 2.4 / 3.9 GHz | 3.7 GHz (All Core) | 30 MB | 125W | 241W | $599 US |
| Core i9-12900 | 8 | 8 | 16 / 24 | 3.2 / 5.2 GHz | 4.9 GHz (All Core) | TBA | TBA | 30 MB | 65W | ~200W | $509 US |
| Core i9-12900T | 8 | 8 | 16 / 24 | TBA / 4.9 GHz | TBA | TBA | TBA | 30 MB | 35W | TBA | TBA |
| Core i7-12700K | 8 | 4 | 12 / 20 | 3.6 / 5.0 GHz | 4.7 GHz (All Core) | 2.7 / 3.8 GHz | 3.6 GHz (All Core) | 25 MB | 125W | 190W | $429 US |
| Core i7-12700 | 8 | 4 | 12 / 20 | 3.6 / 4.9 GHz | 4.6 GHz (All Core) | TBA | TBA | 25 MB | 65W | ~200W | $359 US |
| Core i7-12700T | 8 | 4 | 12 / 20 | TBA / 4.7 GHz | TBA | TBA | TBA | 25 MB | 35W | TBA | TBA |
| Core i5-12600K | 6 | 4 | 10 / 16 | 3.7 / 4.9 GHz | 4.5 GHz (All Core) | 2.8 / 3.6 GHz | 3.4 GHz (All Core) | 20 MB | 125W | 150W | $279 US |
| Core i5-12600 | 6 | 0 | 6 / 12 | 3.7 / 4.8 GHz | 4.4GHz (All Core) | TBA | TBA | 18 MB | 65W | ~200W | $249 US |
| Core i5-12600T | 6 | 0 | 6 / 12 | TBA / 4.6 GHz | TBA | TBA | TBA | 18 MB | 35W | TBA | TBA |
| Core i5-12500T | 6 | 0 | 6 / 12 | TBA / 4.4 GHz | TBA | TBA | TBA | 18 MB | 35W | TBA | TBA |
| Core i5-12400 | 6 | 0 | 6 / 12 | TBA | TBA | TBA | TBA | 18 MB | 65W | ~200W | $203 US |
| Core i5-12400T | 6 | 0 | 6 / 12 | TBA / 4.2 GHz | TBA | TBA | TBA | 18 MB | 35W | TBA | TBA |
| Core i3-12200T | 4 | 0 | 4 / 8 | TBA / 4.2 GHz | TBA | TBA | TBA | 12 MB | 35W | TBA | TBA |
| Core i3-12100T | 4 | 0 | 4 / 8 | TBA / 4.1 GHz | TBA | TBA | TBA | 12 MB | 35W | TBA | TBA |
Source: Wolfstame (on Weibo), @9550pro, VideoCardz