New processors have recently been released, and Qualcomm’s Snapdragon series has been leading the race as the mobile phone business has heated up. High-end smartphones frequently use the Snapdragon 8 Gen 2 processor. Nonetheless, it is inferior than Apple’s A-series processors. With the next Snapdragon 8 Gen 3, which is anticipated to use an Arm Cortex-X4 core, a novel 1+5+2 core arrangement, and TSMC’s N4P manufacturing node, Qualcomm hopes to close that gap.
APPLE A16 BIONIC IS DEFEATED BY QUALCOMM SNAPDRAGON 8 GEN 3 IN GEEKBENCH
A famous mobile device testing application called Geekbench recently published claimed Snapdragon 8 Gen 3 results. The multi core score is significantly higher at 6,236 than the purported single core score of 1,930, which is amazing. These results are far greater than what was previously predicted; prior rumours suggested a single core score of 1,800 and a multi core score of 6,500. These results demonstrate a significant improvement of 30% in single core performance and 20% in multi-core compared to the current generation Snapdragon 8 Gen 2, which averages 1,491 for single core and 5,164 for multi-core.
The Snapdragon 8 Gen 3’s 1+5+2 core arrangement is one of its primary benefits. One high performance core, five midrange cores, and two efficiency cores make up this configuration. This differs from its predecessor’s configuration of 1+4+3. Better power management is made possible by this new arrangement. And it claims to use 20% less energy than the Snapdragon 8 Gen 2 processor. The N4P manufacturing node from TSMC may also be used, which would increase the chip’s effectiveness.
Even if there have been some optimistic speculations and scores have been leaked, it’s crucial to approach this information with some caution. The engineering sample stage of the Snapdragon 8 Gen 3 is currently ongoing. Also, the chip’s performance capabilities may be tested by the developers by pushing the chip to its limits. The performance of the final product can differ from the scores that were leaked. and might need to move more slowly to control thermals.