AMD Launching New CPUs for AM4: Ryzen 5000XT Series Coming in July
During their opening keynote at Computex 2024, AMD announced their intention to launch a pair of new Ryzen 5000 processors for their legacy AM4 platform. The new chips, both getting the XT suffix, will be the Ryzen 9 5900XT, a 16 core Zen 3 part, while the Ryzen 7 5800XT will be an 8 core Zen 3.
The new chips are intended to underscore AMD's ongoing commitment to supporting their consumer platforms over several years. And while the specification changes are rather minor overall – the Zen 3 CPU architecture has long since been taken as far as it can reasonable go – it does give AMD a chance to refresh the platform by slinging hardware at new price points. AMD did something very similar for the Ryzen 3000 generation with the late-model Ryzen 3000 XT chips.
| AMD Ryzen 5000XT Series Processors (Zen 3) |
||||||
| AnandTech | Cores / Threads |
Base Freq |
Turbo Freq |
L2 Cache |
L3 Cache |
TDP |
| Ryzen 9 5950X | 16C / 32T | 3.4 GHz | 4.9 GHz | 8 MB | 64 MB | 105 W |
| Ryzen 9 5900XT | 16C / 32T | 3.3 GHz | 4.8 GHz | 8 MB | 64 MB | 105 W |
| Ryzen 9 5900X | 12C / 24T | 3.7 GHz | 4.8 GHz | 6 MB | 64 MB | 105 W |
| Ryzen 7 5800XT | 8C / 16T | 3.8 GHz | 4.8 GHz | 4 MB | 32 MB | 105 W |
| Ryzen 7 5800X | 8C / 16T | 3.8 GHz | 4.7 GHz | 4 MB | 32 MB | 105 W |
We've dedicated many column inches covering Zen 3 and the Ryzen 5000 series since they launched in late 2020, so there isn't anything new to add here. Zen 3 is no longer AMD's latest and greatest, but the platform as a whole is quite cheap to produce, making it a viable budget offering for new builds, or offering one last upgrade for old builds.
The Ryzen 9 5900XT is a 16 core part, and isn't to be confused with the Ryzen 9 5900X, which is a 12 core part. It ships with a peak turbo clockspeed of 4.8GHz, 100 MHz lower than the top-tier Ryzen 9 5950X. This makes it's XT designation somewhat of a misnomer compared to previous generations of XT chips, although it's clear that AMD has boxed themselves into a corner with their naming scheme, as they both need a way to designate that this is a new chip, and yet still place it below the 5950X.
Looking at the second chip, we have the Ryzen 7 5800XT. This is an 8 core part that does improve on its predecessor, offering a 4.8GHz max turbo clock that is 100MHz higher than the Ryzen 7 5800X's. Both chips otherwise share the same characteristics, including 6 MB of L2 cache and 32 MB of L3 cache, and all four of the chips – including the two new XT series and the corresponding X series chips – all come with a 105 Watt TDP.
In terms of motherboard compatibility, all of the AM4 motherboards that currently support the Ryzen 5000 series are also compatible with the Ryzen 5000XT series, although users are likely to need to perform a firmware update to ensure maximum compatibility; they are the same chips, but the microcodes are likely different.
AMD has provided some gaming performance figures comparing the Ryzen 9 5900XT to Intel's 13th Gen Core i7-13700K. It does offer very modest yet marginal gains in games by up to 4%; it's not mind-blowing, but the... CPUs
Posted by The Techinical Support
![](https://twitter.com/share?url=https://compbuddey.blogspot.com/2024/06/amd-launching-new-cpus-for-am4-ryzen_9.html&text=AMD Launching New CPUs for AM4: Ryzen 5000XT Series Coming in July <p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img src="https://images.anandtech.com/doci/21420/1 Carou_678x452_575px.jpg" alt="" /></a></p><p><p>During their opening keynote at Computex 2024, AMD announced their intention to launch a pair of new Ryzen 5000 processors for their legacy AM4 platform. The new chips, both getting the <em>XT</em> suffix, will be the Ryzen 9 5900XT, a 16 core Zen 3 part, while the Ryzen 7 5800XT will be an 8 core Zen 3.</p>
<p>The new chips are intended to underscore AMD's ongoing commitment to supporting their consumer platforms over several years. And while the specification changes are rather minor overall – the Zen 3 CPU architecture has long since been taken as far as it can reasonable go – it does give AMD a chance to refresh the platform by slinging hardware at new price points. AMD did something very similar for the Ryzen 3000 generation with the late-model <a href="https://www.anandtech.com/show/15897/new-amd-ryzen-3000xt-processors-available-today">Ryzen 3000 XT chips</a>.</p>
<table border="0" style="text-align:center" width="95%">
<tbody>
<tr class="tgrey">
<td colspan="7">AMD Ryzen 5000XT Series Processors<br />
(Zen 3)</td>
</tr>
<tr class="tlblue">
<td><i>AnandTech</i></td>
<td>Cores /<br />
Threads</td>
<td>Base<br />
Freq</td>
<td>Turbo<br />
Freq</td>
<td>L2<br />
Cache</td>
<td>L3<br />
Cache</td>
<td>TDP</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5950X</td>
<td>16C / 32T</td>
<td>3.4 GHz</td>
<td>4.9 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900XT</td>
<td>16C / 32T</td>
<td>3.3 GHz</td>
<td>4.8 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900X</td>
<td>12C / 24T</td>
<td>3.7 GHz</td>
<td>4.8 GHz</td>
<td>6 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800XT</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.8 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800X</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.7 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
</tbody>
</table>
<p>We've dedicated <a href="https://www.anandtech.com/show/16214/amd-zen-3-ryzen-deep-dive-review-5950x-5900x-5800x-and-5700x-tested">many column inches covering Zen 3 and the Ryzen 5000 series since they launched in late 2020</a>, so there isn't anything new to add here. Zen 3 is no longer AMD's latest and greatest, but the platform as a whole is quite cheap to produce, making it a viable budget offering for new builds, or offering one last upgrade for old builds.</p>
<p>The Ryzen 9 5900XT is a 16 core part, and isn't to be confused with the Ryzen 9 5900X, which is a 12 core part. It ships with a peak turbo clockspeed of 4.8GHz, 100 MHz lower than the top-tier Ryzen 9 5950X. This makes it's XT designation somewhat of a misnomer compared to previous generations of XT chips, although it's clear that AMD has boxed themselves into a corner with their naming scheme, as they both need a way to designate that this is a new chip, and yet still place it below the 5950X.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2819%29.png" style="width: 100%;" /></a></p>
<p>Looking at the second chip, we have the Ryzen 7 5800XT. This is an 8 core part that does improve on its predecessor, offering a 4.8GHz max turbo clock that is 100MHz higher than the Ryzen 7 5800X's. Both chips otherwise share the same characteristics, including 6 MB of L2 cache and 32 MB of L3 cache, and all four of the chips – including the two new XT series and the corresponding X series chips – all come with a 105 Watt TDP.</p>
<p>In terms of motherboard compatibility, all of the AM4 motherboards that currently support the Ryzen 5000 series are also compatible with the Ryzen 5000XT series, although users are likely to need to perform a firmware update to ensure maximum compatibility; they are the same chips, but the microcodes are likely different.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2820%29.png" style="width: 100%;" /></a></p>
<p>AMD has provided some gaming performance figures comparing the Ryzen 9 5900XT to Intel's 13th Gen Core i7-13700K. It does offer very modest yet marginal gains in games by up to 4%; it's not mind-blowing, but the... CPUs){kind=link}
![](https://www.pinterest.com/pin/create/button/?url=https://compbuddey.blogspot.com/2024/06/amd-launching-new-cpus-for-am4-ryzen_9.html&media=https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uXY1WtfObztzg4nFbITG3YbBLzcKXa3ViwhA5IbyTGpr97jnxK7QDiuyINDsaQMhAtFjQ08e-Z9RYgpN0SGJDiedWRnkQj6jK4OLiUsjEy4jLQZz-EgSpHWb9dMOV4h8yQf5KcYKc&description=AMD Launching New CPUs for AM4: Ryzen 5000XT Series Coming in July <p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img src="https://images.anandtech.com/doci/21420/1 Carou_678x452_575px.jpg" alt="" /></a></p><p><p>During their opening keynote at Computex 2024, AMD announced their intention to launch a pair of new Ryzen 5000 processors for their legacy AM4 platform. The new chips, both getting the <em>XT</em> suffix, will be the Ryzen 9 5900XT, a 16 core Zen 3 part, while the Ryzen 7 5800XT will be an 8 core Zen 3.</p>
<p>The new chips are intended to underscore AMD's ongoing commitment to supporting their consumer platforms over several years. And while the specification changes are rather minor overall – the Zen 3 CPU architecture has long since been taken as far as it can reasonable go – it does give AMD a chance to refresh the platform by slinging hardware at new price points. AMD did something very similar for the Ryzen 3000 generation with the late-model <a href="https://www.anandtech.com/show/15897/new-amd-ryzen-3000xt-processors-available-today">Ryzen 3000 XT chips</a>.</p>
<table border="0" style="text-align:center" width="95%">
<tbody>
<tr class="tgrey">
<td colspan="7">AMD Ryzen 5000XT Series Processors<br />
(Zen 3)</td>
</tr>
<tr class="tlblue">
<td><i>AnandTech</i></td>
<td>Cores /<br />
Threads</td>
<td>Base<br />
Freq</td>
<td>Turbo<br />
Freq</td>
<td>L2<br />
Cache</td>
<td>L3<br />
Cache</td>
<td>TDP</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5950X</td>
<td>16C / 32T</td>
<td>3.4 GHz</td>
<td>4.9 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900XT</td>
<td>16C / 32T</td>
<td>3.3 GHz</td>
<td>4.8 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900X</td>
<td>12C / 24T</td>
<td>3.7 GHz</td>
<td>4.8 GHz</td>
<td>6 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800XT</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.8 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800X</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.7 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
</tbody>
</table>
<p>We've dedicated <a href="https://www.anandtech.com/show/16214/amd-zen-3-ryzen-deep-dive-review-5950x-5900x-5800x-and-5700x-tested">many column inches covering Zen 3 and the Ryzen 5000 series since they launched in late 2020</a>, so there isn't anything new to add here. Zen 3 is no longer AMD's latest and greatest, but the platform as a whole is quite cheap to produce, making it a viable budget offering for new builds, or offering one last upgrade for old builds.</p>
<p>The Ryzen 9 5900XT is a 16 core part, and isn't to be confused with the Ryzen 9 5900X, which is a 12 core part. It ships with a peak turbo clockspeed of 4.8GHz, 100 MHz lower than the top-tier Ryzen 9 5950X. This makes it's XT designation somewhat of a misnomer compared to previous generations of XT chips, although it's clear that AMD has boxed themselves into a corner with their naming scheme, as they both need a way to designate that this is a new chip, and yet still place it below the 5950X.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2819%29.png" style="width: 100%;" /></a></p>
<p>Looking at the second chip, we have the Ryzen 7 5800XT. This is an 8 core part that does improve on its predecessor, offering a 4.8GHz max turbo clock that is 100MHz higher than the Ryzen 7 5800X's. Both chips otherwise share the same characteristics, including 6 MB of L2 cache and 32 MB of L3 cache, and all four of the chips – including the two new XT series and the corresponding X series chips – all come with a 105 Watt TDP.</p>
<p>In terms of motherboard compatibility, all of the AM4 motherboards that currently support the Ryzen 5000 series are also compatible with the Ryzen 5000XT series, although users are likely to need to perform a firmware update to ensure maximum compatibility; they are the same chips, but the microcodes are likely different.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2820%29.png" style="width: 100%;" /></a></p>
<p>AMD has provided some gaming performance figures comparing the Ryzen 9 5900XT to Intel's 13th Gen Core i7-13700K. It does offer very modest yet marginal gains in games by up to 4%; it's not mind-blowing, but the... CPUs){kind=link}
![](https://web.whatsapp.com/send?text=AMD Launching New CPUs for AM4: Ryzen 5000XT Series Coming in July <p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img src="https://images.anandtech.com/doci/21420/1 Carou_678x452_575px.jpg" alt="" /></a></p><p><p>During their opening keynote at Computex 2024, AMD announced their intention to launch a pair of new Ryzen 5000 processors for their legacy AM4 platform. The new chips, both getting the <em>XT</em> suffix, will be the Ryzen 9 5900XT, a 16 core Zen 3 part, while the Ryzen 7 5800XT will be an 8 core Zen 3.</p>
<p>The new chips are intended to underscore AMD's ongoing commitment to supporting their consumer platforms over several years. And while the specification changes are rather minor overall – the Zen 3 CPU architecture has long since been taken as far as it can reasonable go – it does give AMD a chance to refresh the platform by slinging hardware at new price points. AMD did something very similar for the Ryzen 3000 generation with the late-model <a href="https://www.anandtech.com/show/15897/new-amd-ryzen-3000xt-processors-available-today">Ryzen 3000 XT chips</a>.</p>
<table border="0" style="text-align:center" width="95%">
<tbody>
<tr class="tgrey">
<td colspan="7">AMD Ryzen 5000XT Series Processors<br />
(Zen 3)</td>
</tr>
<tr class="tlblue">
<td><i>AnandTech</i></td>
<td>Cores /<br />
Threads</td>
<td>Base<br />
Freq</td>
<td>Turbo<br />
Freq</td>
<td>L2<br />
Cache</td>
<td>L3<br />
Cache</td>
<td>TDP</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5950X</td>
<td>16C / 32T</td>
<td>3.4 GHz</td>
<td>4.9 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900XT</td>
<td>16C / 32T</td>
<td>3.3 GHz</td>
<td>4.8 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900X</td>
<td>12C / 24T</td>
<td>3.7 GHz</td>
<td>4.8 GHz</td>
<td>6 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800XT</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.8 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800X</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.7 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
</tbody>
</table>
<p>We've dedicated <a href="https://www.anandtech.com/show/16214/amd-zen-3-ryzen-deep-dive-review-5950x-5900x-5800x-and-5700x-tested">many column inches covering Zen 3 and the Ryzen 5000 series since they launched in late 2020</a>, so there isn't anything new to add here. Zen 3 is no longer AMD's latest and greatest, but the platform as a whole is quite cheap to produce, making it a viable budget offering for new builds, or offering one last upgrade for old builds.</p>
<p>The Ryzen 9 5900XT is a 16 core part, and isn't to be confused with the Ryzen 9 5900X, which is a 12 core part. It ships with a peak turbo clockspeed of 4.8GHz, 100 MHz lower than the top-tier Ryzen 9 5950X. This makes it's XT designation somewhat of a misnomer compared to previous generations of XT chips, although it's clear that AMD has boxed themselves into a corner with their naming scheme, as they both need a way to designate that this is a new chip, and yet still place it below the 5950X.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2819%29.png" style="width: 100%;" /></a></p>
<p>Looking at the second chip, we have the Ryzen 7 5800XT. This is an 8 core part that does improve on its predecessor, offering a 4.8GHz max turbo clock that is 100MHz higher than the Ryzen 7 5800X's. Both chips otherwise share the same characteristics, including 6 MB of L2 cache and 32 MB of L3 cache, and all four of the chips – including the two new XT series and the corresponding X series chips – all come with a 105 Watt TDP.</p>
<p>In terms of motherboard compatibility, all of the AM4 motherboards that currently support the Ryzen 5000 series are also compatible with the Ryzen 5000XT series, although users are likely to need to perform a firmware update to ensure maximum compatibility; they are the same chips, but the microcodes are likely different.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2820%29.png" style="width: 100%;" /></a></p>
<p>AMD has provided some gaming performance figures comparing the Ryzen 9 5900XT to Intel's 13th Gen Core i7-13700K. It does offer very modest yet marginal gains in games by up to 4%; it's not mind-blowing, but the... CPUs | https://compbuddey.blogspot.com/2024/06/amd-launching-new-cpus-for-am4-ryzen_9.html){kind=link}
![](mailto:?subject=AMD Launching New CPUs for AM4: Ryzen 5000XT Series Coming in July <p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img src="https://images.anandtech.com/doci/21420/1 Carou_678x452_575px.jpg" alt="" /></a></p><p><p>During their opening keynote at Computex 2024, AMD announced their intention to launch a pair of new Ryzen 5000 processors for their legacy AM4 platform. The new chips, both getting the <em>XT</em> suffix, will be the Ryzen 9 5900XT, a 16 core Zen 3 part, while the Ryzen 7 5800XT will be an 8 core Zen 3.</p>
<p>The new chips are intended to underscore AMD's ongoing commitment to supporting their consumer platforms over several years. And while the specification changes are rather minor overall – the Zen 3 CPU architecture has long since been taken as far as it can reasonable go – it does give AMD a chance to refresh the platform by slinging hardware at new price points. AMD did something very similar for the Ryzen 3000 generation with the late-model <a href="https://www.anandtech.com/show/15897/new-amd-ryzen-3000xt-processors-available-today">Ryzen 3000 XT chips</a>.</p>
<table border="0" style="text-align:center" width="95%">
<tbody>
<tr class="tgrey">
<td colspan="7">AMD Ryzen 5000XT Series Processors<br />
(Zen 3)</td>
</tr>
<tr class="tlblue">
<td><i>AnandTech</i></td>
<td>Cores /<br />
Threads</td>
<td>Base<br />
Freq</td>
<td>Turbo<br />
Freq</td>
<td>L2<br />
Cache</td>
<td>L3<br />
Cache</td>
<td>TDP</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5950X</td>
<td>16C / 32T</td>
<td>3.4 GHz</td>
<td>4.9 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900XT</td>
<td>16C / 32T</td>
<td>3.3 GHz</td>
<td>4.8 GHz</td>
<td>8 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 9 5900X</td>
<td>12C / 24T</td>
<td>3.7 GHz</td>
<td>4.8 GHz</td>
<td>6 MB</td>
<td>64 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800XT</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.8 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
<tr>
<td class="tlgrey">Ryzen 7 5800X</td>
<td>8C / 16T</td>
<td>3.8 GHz</td>
<td>4.7 GHz</td>
<td>4 MB</td>
<td>32 MB</td>
<td>105 W</td>
</tr>
</tbody>
</table>
<p>We've dedicated <a href="https://www.anandtech.com/show/16214/amd-zen-3-ryzen-deep-dive-review-5950x-5900x-5800x-and-5700x-tested">many column inches covering Zen 3 and the Ryzen 5000 series since they launched in late 2020</a>, so there isn't anything new to add here. Zen 3 is no longer AMD's latest and greatest, but the platform as a whole is quite cheap to produce, making it a viable budget offering for new builds, or offering one last upgrade for old builds.</p>
<p>The Ryzen 9 5900XT is a 16 core part, and isn't to be confused with the Ryzen 9 5900X, which is a 12 core part. It ships with a peak turbo clockspeed of 4.8GHz, 100 MHz lower than the top-tier Ryzen 9 5950X. This makes it's XT designation somewhat of a misnomer compared to previous generations of XT chips, although it's clear that AMD has boxed themselves into a corner with their naming scheme, as they both need a way to designate that this is a new chip, and yet still place it below the 5950X.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2819%29.png" style="width: 100%;" /></a></p>
<p>Looking at the second chip, we have the Ryzen 7 5800XT. This is an 8 core part that does improve on its predecessor, offering a 4.8GHz max turbo clock that is 100MHz higher than the Ryzen 7 5800X's. Both chips otherwise share the same characteristics, including 6 MB of L2 cache and 32 MB of L3 cache, and all four of the chips – including the two new XT series and the corresponding X series chips – all come with a 105 Watt TDP.</p>
<p>In terms of motherboard compatibility, all of the AM4 motherboards that currently support the Ryzen 5000 series are also compatible with the Ryzen 5000XT series, although users are likely to need to perform a firmware update to ensure maximum compatibility; they are the same chips, but the microcodes are likely different.</p>
<p align="center"><a href="https://www.anandtech.com/show/21420/amd-launching-new-cpus-for-am4-ryzen-5000xt-series-coming-in-july"><img alt="" src="https://images.anandtech.com/doci/21420/AMD%20COMPUTEX%20CLIENT%20PRESS%20DECK-01-01%20%2820%29.png" style="width: 100%;" /></a></p>
<p>AMD has provided some gaming performance figures comparing the Ryzen 9 5900XT to Intel's 13th Gen Core i7-13700K. It does offer very modest yet marginal gains in games by up to 4%; it's not mind-blowing, but the... CPUs&body=https://compbuddey.blogspot.com/2024/06/amd-launching-new-cpus-for-am4-ryzen_9.html){kind=link}
U.S. Signs $1.5B in CHIPS Act Agreements With Amkor and SKhynix for Chip Packaging Plants 
Under the CHIPS & Science Act, the U.S. government provided tens of billions of dollars in grants and loans to the world's leading maker of chips, such as Intel, Samsung, and TSMC, which will significantly expand the country's semiconductor production industry in the coming years. However, most chips are typically tested, assembled, and packaged in Asia, which has left the American supply chain incomplete. Addressing this last gap in the government's domestic chip production plans, these past couple of weeks the U.S. government signed memorandums of understanding worth about $1.5 billion with Amkor and SK hynix to support their efforts to build chip packaging facilities in the U.S.
Amkor to Build Advanced Packaging Facility with Apple in Mind
Amkor plans to build a $2 billion advanced packaging facility near Peoria, Arizona, to test and assemble chips produced by TSMC at its Fab 21 near Phoenix, Arizona. The company signed a MOU that offers $400 million in direct funding and access to $200 million in loans under the CHIPS & Science Act. In addition, the company plans to take advantage of a 25% investment tax credit on eligible capital expenditures.
Set to be strategically positioned near TSMC's upcoming Fab 21 complex in Arizona, Amkor's Peoria facility will occupy 55 acres and, when fully completed, will feature over 500,000 square feet (46,451 square meters) of cleanroom space, more than twice the size of Amkor's advanced packaging site in Vietnam. Although the company has not disclosed the exact capacity or the specific technologies the facility will support, it is expected to cater to a wide range of industries, including automotive, high-performance computing, and mobile technologies. This suggests the new plant will offer diverse packaging solutions, including traditional, 2.5D, and 3D technologies.
Amkor has collaborated extensively with Apple on the vision and initial setup of the Peoria facility, as Apple is slated to be the facility's first and largest customer, marking a significant commitment from the tech giant. This partnership highlights the importance of the new facility in reinforcing the U.S. semiconductor supply chain and positioning Amkor as a key partner for companies relying on TSMC's manufacturing capabilities. The project is expected to generate around 2,000 jobs and is scheduled to begin operations in 2027.
SK hynix to Build HBM4 in the U.S.
This week SK hynix also signed a preliminary agreement with the U.S. government to receive up to $450 million in direct funding and $500 million in loans to build an advanced memory packaging facility in West Lafayette, Indiana.
The proposed facility is scheduled to begin operations in 2028, which means that it will assemble HBM4 or HBM4E memory. Meanwhile, DRAM devices for high bandwidth memory (HBM) stacks will still be produced in South Korea. Nonetheless, packing finished HBM4/HBM4E in the U.S. and possibly integrating these memory modules with high-end processors is a big deal.
In addition to building its packaging plant, SK hynix plans to collaborate with Purdue University and other local research institutions to advance semiconductor technology and packaging innovations. This partnership is intended to bolster research and development in the region, positioning the facility as a hub for AI technology and skilled employment.
Semiconductors
U.S. Signs $1.5B in CHIPS Act Agreements With Amkor and SKhynix for Chip Packaging Plants
Under the CHIPS & Science Act, the U.S. government provided tens of billions of dollars in grants and loans to the world's leading maker of chips, such as Intel, Samsung, and TSMC, which will significantly expand the country's semiconductor production industry in the coming years. However, most chips are typically tested, assembled, and packaged in Asia, which has left the American supply chain incomplete. Addressing this last gap in the government's domestic chip production plans, these past couple of weeks the U.S. government signed memorandums of understanding worth about $1.5 billion with Amkor and SK hynix to support their efforts to build chip packaging facilities in the U.S.
Amkor to Build Advanced Packaging Facility with Apple in Mind
Amkor plans to build a $2 billion advanced packaging facility near Peoria, Arizona, to test and assemble chips produced by TSMC at its Fab 21 near Phoenix, Arizona. The company signed a MOU that offers $400 million in direct funding and access to $200 million in loans under the CHIPS & Science Act. In addition, the company plans to take advantage of a 25% investment tax credit on eligible capital expenditures.
Set to be strategically positioned near TSMC's upcoming Fab 21 complex in Arizona, Amkor's Peoria facility will occupy 55 acres and, when fully completed, will feature over 500,000 square feet (46,451 square meters) of cleanroom space, more than twice the size of Amkor's advanced packaging site in Vietnam. Although the company has not disclosed the exact capacity or the specific technologies the facility will support, it is expected to cater to a wide range of industries, including automotive, high-performance computing, and mobile technologies. This suggests the new plant will offer diverse packaging solutions, including traditional, 2.5D, and 3D technologies.
Amkor has collaborated extensively with Apple on the vision and initial setup of the Peoria facility, as Apple is slated to be the facility's first and largest customer, marking a significant commitment from the tech giant. This partnership highlights the importance of the new facility in reinforcing the U.S. semiconductor supply chain and positioning Amkor as a key partner for companies relying on TSMC's manufacturing capabilities. The project is expected to generate around 2,000 jobs and is scheduled to begin operations in 2027.
SK hynix to Build HBM4 in the U.S.
This week SK hynix also signed a preliminary agreement with the U.S. government to receive up to $450 million in direct funding and $500 million in loans to build an advanced memory packaging facility in West Lafayette, Indiana.
The proposed facility is scheduled to begin operations in 2028, which means that it will assemble HBM4 or HBM4E memory. Meanwhile, DRAM devices for high bandwidth memory (HBM) stacks will still be produced in South Korea. Nonetheless, packing finished HBM4/HBM4E in the U.S. and possibly integrating these memory modules with high-end processors is a big deal.
In addition to building its packaging plant, SK hynix plans to collaborate with Purdue University and other local research institutions to advance semiconductor technology and packaging innovations. This partnership is intended to bolster research and development in the region, positioning the facility as a hub for AI technology and skilled employment.
Semiconductors
Western Digital Introduces 4 TB microSDUC, 8 TB SDUC, and 16 TB External SSDs 
Western Digital's BiCS8 218-layer 3D NAND is being put to good use in a wide range of client and enterprise platforms, including WD's upcoming Gen 5 client SSDs and 128 TB-class datacenter SSD. On the external storage front, the company demonstrated four different products: for card-based media, 4 TB microSDUC and 8 TB SDUC cards with UHS-I speeds, and on the portable SSD front we had two 16 TB drives. One will be a SanDisk Desk Drive with external power, and the other in the SanDisk Extreme Pro housing with a lanyard opening in the case.
All of these are using BiCS8 QLC NAND, though I did hear booth talk (as I was taking leave) that they were not supposed to divulge the use of QLC in these products. The 4 TB microSDUC and 8 TB SDUC cards are rated for UHS-I speeds. They are being marketed under the SanDisk Ultra branding.
The SanDisk Desk Drive is an external SSD with a 18W power adapter, and it has been in the market for a few months now. Initially launched in capacities up to 8 TB, Western Digital had promised a 16 TB version before the end of the year. It appears that the product is coming to retail quite soon. One aspect to note is that this drive has been using TLC for the SKUs that are currently in the market, so it appears unlikely that the 16 TB version would be QLC. The units (at least up to the 8 TB capacity point) come with two SN850XE drives. Given the recent introduction of the 8 TB SN850X, an 'E' version with tweaked firmware is likely to be present in the 16 TB Desk Drive.
The 16 TB portable SSD in the SanDisk Extreme housing was a technology demonstration. It is definitely the highest capacity bus-powered portable SSD demonstrated by any vendor at any trade show thus far. Given the 16 TB Desk Drive's imminent market introduction, it is just a matter of time before the technology demonstration of the bus-powered version becomes a retail reality.
Storage
Kioxia Demonstrates Optical Interface SSDs for Data Centers 
A few years back, the Japanese government's New Energy and Industrial Technology Development Organization (NEDO ) allocated funding for the development of green datacenter technologies. With the aim to obtain up to 40% savings in overall power consumption, several Japanese companies have been developing an optical interface for their enterprise SSDs. And at this year's FMS, Kioxia had their optical interface on display.
For this demonstration, Kioxia took its existing CM7 enterprise SSD and created an optical interface for it. A PCIe card with on-board optics developed by Kyocera is installed in the server slot. An optical interface allows data transfer over long distances (it was 40m in the demo, but Kioxia promises lengths of up to 100m for the cable in the future). This allows the storage to be kept in a separate room with minimal cooling requirements compared to the rack with the CPUs and GPUs. Disaggregation of different server components will become an option as very high throughput interfaces such as PCIe 7.0 (with 128 GT/s rates) become available.
The demonstration of the optical SSD showed a slight loss in IOPS performance, but a significant advantage in the latency metric over the shipping enterprise SSD behind a copper network link. Obviously, there are advantages in wiring requirements and signal integrity maintenance with optical links.
Being a proof-of-concept demonstration, we do see the requirement for an industry-standard approach if this were to gain adoption among different datacenter vendors. The PCI-SIG optical workgroup will need to get its act together soon to create a standards-based approach to this problem.
Storage
![Rapidus Wants to Offer Fully Automated Packaging for 2nm Fab to Cut Chip Lead Times <p align="center"><a href="https://www.anandtech.com/show/21525/rapidus-2nm-fully-automated-chip-packaging-to-cut-lead-times"><img src="https://images.anandtech.com/doci/21525/intel-foundry-wafer-semiconductor-fab-ifs-678_575px.jpg" alt="" /></a></p><p><p>One of the core challenges that Rapidus will face when it kicks off volume production of chips on its 2nm-class process technology in 2027 is lining up customers. With Intel, Samsung, and TSMC all slated to offer their own 2nm-class nodes by that time, Rapidus will need some kind of advantage to attract customers away from its more established rivals. To that end, the company thinks they've found their edge: fully automated packaging that will allow for shorter chip lead times than manned packaging operations.</p>
<p>In an interview with <a href="https://asia.nikkei.com/Editor-s-Picks/Interview/Japan-s-Rapidus-to-fully-automate-2-nm-chip-fab-president-says">Nikkei</a>, Rapidus' president, Atsuyoshi Koike, outlined the company's vision to use advanced packaging as a competitive edge for the new fab. <a href="https://www.anandtech.com/show/21411/rapidus-adds-chip-packaging-services-to-plans-for-32b-2nm-fab">The Hokkaido facility</a>, which is currently under construction and is expecting to begin equipment installation this December, is already slated to both produce chips and offer advanced packaging services within the same facility, an industry first. But ultimately, Rapidus biggest plan to differentiate itself is by automating the back-end fab processes (chip packaging) to provide significantly faster turnaround times.</p>
<p>Rapidus is targetting back-end production in particular as, compared to front-end (lithography) production, back-end production still heavily relies on human labor. No other advanced packaging fab has fully automated the process thus far, which provides for a degree of flexibility, but slows throughput. But with automation in place to handle this aspect of chip production, Rapidus would be able to increase chip packaging efficiency and speed, which is crucial as chip assembly tasks become more complex. Rapidus is also collaborating with multiple Japanese suppliers to source materials for back-end production. </p>
<p>"In the past, Japanese chipmakers tried to keep their technology development exclusively in-house, which pushed up development costs and made them less competitive," Koike told Nikkei. "[Rapidus plans to] open up technology that should be standardized, bringing down costs, while handling important technology in-house." </p>
<p>Financially, Rapidus faces a significant challenge, needing a total of ¥5 trillion ($35 billion) by the time mass production starts in 2027. The company estimates that ¥2 trillion will be required by 2025 for prototype production. While the Japanese government has provided ¥920 billion in aid, Rapidus still needs to secure substantial funding from private investors.</p>
<p>Due to its lack of track record and experience of chip production as. well as limited visibility for success, Rapidus is finding it difficult to attract private financing. The company is in discussions with the government to make it easier to raise capital, including potential loan guarantees, and is hopeful that new legislation will assist in this effort.</p>
</p> Semiconductors](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sKngk92KkOJOIKHl_OToKROeACufJ3UYorgA1L5--tXQ2n95pErkWhZuOoCJ4vfdQbaMZQ_F2ZEJQ7V4lajyFeXZC5K4wkgWUwL77OyaYXbFepvowoNjF7Pe4cgpQn3fJ6vT7-mp5RtC2MyK9FZx971TkgnEvl289may5LKcuj6d1o=w72-h72-p-k-no-nu)
Rapidus Wants to Offer Fully Automated Packaging for 2nm Fab to Cut Chip Lead Times 
One of the core challenges that Rapidus will face when it kicks off volume production of chips on its 2nm-class process technology in 2027 is lining up customers. With Intel, Samsung, and TSMC all slated to offer their own 2nm-class nodes by that time, Rapidus will need some kind of advantage to attract customers away from its more established rivals. To that end, the company thinks they've found their edge: fully automated packaging that will allow for shorter chip lead times than manned packaging operations.
In an interview with Nikkei, Rapidus' president, Atsuyoshi Koike, outlined the company's vision to use advanced packaging as a competitive edge for the new fab. The Hokkaido facility, which is currently under construction and is expecting to begin equipment installation this December, is already slated to both produce chips and offer advanced packaging services within the same facility, an industry first. But ultimately, Rapidus biggest plan to differentiate itself is by automating the back-end fab processes (chip packaging) to provide significantly faster turnaround times.
Rapidus is targetting back-end production in particular as, compared to front-end (lithography) production, back-end production still heavily relies on human labor. No other advanced packaging fab has fully automated the process thus far, which provides for a degree of flexibility, but slows throughput. But with automation in place to handle this aspect of chip production, Rapidus would be able to increase chip packaging efficiency and speed, which is crucial as chip assembly tasks become more complex. Rapidus is also collaborating with multiple Japanese suppliers to source materials for back-end production.
"In the past, Japanese chipmakers tried to keep their technology development exclusively in-house, which pushed up development costs and made them less competitive," Koike told Nikkei. "[Rapidus plans to] open up technology that should be standardized, bringing down costs, while handling important technology in-house."
Financially, Rapidus faces a significant challenge, needing a total of ¥5 trillion ($35 billion) by the time mass production starts in 2027. The company estimates that ¥2 trillion will be required by 2025 for prototype production. While the Japanese government has provided ¥920 billion in aid, Rapidus still needs to secure substantial funding from private investors.
Due to its lack of track record and experience of chip production as. well as limited visibility for success, Rapidus is finding it difficult to attract private financing. The company is in discussions with the government to make it easier to raise capital, including potential loan guarantees, and is hopeful that new legislation will assist in this effort.
Semiconductors
Lorem Ipsum is simply dummy text of the printing and typesetting industry. Lorem Ipsum has been the industry's.
U.S. Signs $1.5B in CHIPS Act Agreements With Amkor and SKhynix for Chip Packaging Plants
Under the CHIPS & Science Act, the U.S. government provided tens of billions of dollars in grants and loans to the world's leading maker of chips, such as Intel, Samsung, and TSMC, which will significantly expand the country's semiconductor production industry in the coming years. However, most chips are typically tested, assembled, and packaged in Asia, which has left the American supply chain incomplete. Addressing this last gap in the government's domestic chip production plans, these past couple of weeks the U.S. government signed memorandums of understanding worth about $1.5 billion with Amkor and SK hynix to support their efforts to build chip packaging facilities in the U.S.
Amkor to Build Advanced Packaging Facility with Apple in Mind
Amkor plans to build a $2 billion advanced packaging facility near Peoria, Arizona, to test and assemble chips produced by TSMC at its Fab 21 near Phoenix, Arizona. The company signed a MOU that offers $400 million in direct funding and access to $200 million in loans under the CHIPS & Science Act. In addition, the company plans to take advantage of a 25% investment tax credit on eligible capital expenditures.
Set to be strategically positioned near TSMC's upcoming Fab 21 complex in Arizona, Amkor's Peoria facility will occupy 55 acres and, when fully completed, will feature over 500,000 square feet (46,451 square meters) of cleanroom space, more than twice the size of Amkor's advanced packaging site in Vietnam. Although the company has not disclosed the exact capacity or the specific technologies the facility will support, it is expected to cater to a wide range of industries, including automotive, high-performance computing, and mobile technologies. This suggests the new plant will offer diverse packaging solutions, including traditional, 2.5D, and 3D technologies.
Amkor has collaborated extensively with Apple on the vision and initial setup of the Peoria facility, as Apple is slated to be the facility's first and largest customer, marking a significant commitment from the tech giant. This partnership highlights the importance of the new facility in reinforcing the U.S. semiconductor supply chain and positioning Amkor as a key partner for companies relying on TSMC's manufacturing capabilities. The project is expected to generate around 2,000 jobs and is scheduled to begin operations in 2027.
SK hynix to Build HBM4 in the U.S.
This week SK hynix also signed a preliminary agreement with the U.S. government to receive up to $450 million in direct funding and $500 million in loans to build an advanced memory packaging facility in West Lafayette, Indiana.
The proposed facility is scheduled to begin operations in 2028, which means that it will assemble HBM4 or HBM4E memory. Meanwhile, DRAM devices for high bandwidth memory (HBM) stacks will still be produced in South Korea. Nonetheless, packing finished HBM4/HBM4E in the U.S. and possibly integrating these memory modules with high-end processors is a big deal.
In addition to building its packaging plant, SK hynix plans to collaborate with Purdue University and other local research institutions to advance semiconductor technology and packaging innovations. This partnership is intended to bolster research and development in the region, positioning the facility as a hub for AI technology and skilled employment.
Semiconductors
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