Google’s first-gen in-house silicon, Google Tensor, was introduced earlier last year with the Pixel 6 series launch. Now, after almost a year, Google has unveiled the Google Tensor G2 chipset with the Pixel 7 series. The second-gen Google silicon is supposed to bring marginal improvements in CPU performance and significant gains in the GPU department. However, how well does the Google Tensor G2 stack up against the Qualcomm Snapdragon 8+ Gen 1 and Apple’s A16 Bionic? To find the answer, go through our comparison between the Google Tensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic. We have discussed CPU, GPU, TPU (AI and ML), ISP, 5G modem, benchmark numbers, and more.

In this comparison between the Google Tensor G2, Snapdragon 8+ Gen 1, and A16 Bionic, we have analyzed the CPU architecture, GPU performance, benchmark numbers, and more.

  • Tensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: SpecificationsTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: CPUTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: GPUTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: Geekbench and AnTuTu Benchmark NumbersTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: ISPTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: AI and MLTensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: Wireless Connectivity

Tensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: Specifications

Here, we have mentioned the detailed specs sheet for the Google Tensor G2, Snapdragon 8+ Gen 1, and A16 Bionic chipset. Glance over it to get a rough idea about all three processors.

Tensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: CPU

Beginning with the CPU, the Google Tensor G2 has not seen any significant changes compared to Google’s first in-house chipset, the OG Google Tensor. The CPU architecture is the same as last year’s SoC, which includes two Cortex-X1 cores, two Cortex-A78 cores (replaced A76), and four Cortex-A55 cores. The only difference with Tensor G2 is that the ARM Cortex-X1 core is clocked slightly higher at 2.85GHz instead of 2.80GHz and the Cortex-A78 core is clocked at 2.35GHz.

In tandem, you’re getting almost an identical CPU on the Google Tensor G2, and the benchmark results (more on this below) also reflect the same trend. You don’t get the newer and improved Cortex-X2, A715, A710, or A510 core, which is quite disappointing.

Apple’s A16 Bionic chipset, on the other hand, is altogether on another level. Instead of an octa-core architecture, it goes for a hexa-core cluster with two high-performance cores (“Everest” clocked at 3.46GHz) and four high-efficiency cores (“Sawtooth” clocked at 2.02GHz). Simply put, in terms of CPU performance, the Tensor G2 SoC is nowhere closer to either Qualcomm or Apple’s offering.

Coming to the GPU, Google has indeed packed a newer and more power-efficient 7-core Mali G710 MP7 GPU on the Google Tensor G2. It’s said to bring a 20% performance improvement over the Mali G78 GPU used in last year’s Tensor chipset. At the same time, it consumes 20% less energy, which is great for thermal efficiency.

Note that the Mali G710 GPU can be configured starting from 7 to 16 cores, but Google has packed only 7 cores on the Tensor G2, perhaps to keep thermal efficiency in check. For your information, other phone manufacturers like Xiaomi and Asus have gone with a 10-core Mali-G710 MC10 setup.

At least with the 10-core GPU, Google could have put up a decent fight against SD8+ Gen 1 and A16 Bionic. But it seems like Google is playing safe and does not want any kind of heating issues on the Pixel 7 series. To sum up, the GPU on the Tensor G2 is quite power-efficient and powerful, but due to lower cores, Google loses out to Qualcomm and Apple.

Talking about benchmark numbers of Google Tensor G2, Snapdragon 8+ Gen 1, and A16 Bionic, let’s begin with Geekbench single-core and multi-core CPU tests. As you can see here, the CPU on the Google Tensor G2 is marginally better than last year’s Google Tensor (2021). And when compared with Snapdragon 8+ Gen 1 and A16 Bionic, it’s miles behind. In fact, the Google Tensor G2 is close to Snapdragon 888+ in terms of CPU performance.

If we go by the recently leaked AnTuTu score of Google Tensor G2, Snapdragon 8+ Gen 1, and A16 Bionic, Google again disappoints with its latest silicon. The Tensor G2 chipset scores 801,116 in the AnTuTu test and is way behind SD8+ Gen 1 and A16 Bionic.

Tensor G2 vs Snapdragon 8+ Gen 1 vs A16 Bionic: ISP

While the Google Tensor G2 is behind the Snapdragon 8+ Gen 1 and Apple A16 Bionic in CPU performance and is promising in the GPU department, ISP is where Google shines. And that’s because it controls both the hardware and software verticals. Along with all the photo and video capabilities, the custom Google ISP offers cinematic blur for videos, 2x faster Night Sight photography, and 10-bit HDR support. You also get active stabilization using both hardware and software, along with 4K 60FPS shooting across all the cameras.

If we talk about the ISP on the Snapdragon 8+ Gen 1, well, it’s definitely more powerful and offers an 18-bit triple ISP architecture. It can capture 3.2 gigapixels per second and supports 8K HDR recording as well. The ISP on the A16 Bionic is also quite advanced and can perform 4 trillion operations per photo. It powers the new Photonic engine for generating sharper and rich images and offers Cinematic videos and Action mode to stabilize shaky videos.

Overall, I would say all three ISPs are plenty powerful, but at the end of the day, it depends on the phone manufacturer on how to leverage these hardware capabilities. And it seems like Google is winning this game with new and exciting camera features that are meaningful to the user.

In the AI and ML segment, Google is a leader in providing useful features on Pixel phones. And on the Tensor G2 chipset, Google has added a new TPU (Tensor Processing Unit) that can deliver state-of-the-art AI and personal intelligence features to your phone.

In the keynote address, Google said that machine learning runs up to 60% faster on the Tensor G2 chip with 20% more power efficiency. From speech recognition to translating conversations, voice assistance, Pixel Call Assist, Call Screen, Super Res Zoom, etc., you get all the AI-driven features on the Pixel lineup, thanks to its powerful TPU.

On the other hand, Apple’s new 16-core Neural Engine on the A16 Bionic can perform 17 trillion operations per second, which helps in computational photography, voice assistance, pixel-by-pixel analysis, speech recognition, etc. However, no other company comes close to Google in delivering smart and personalized experiences, so the Google Tensor G2 wins this round as well.

The Google Tensor G2 chip features Samsung’s unannounced G5300B 5G modem, which supports both mmWave and sub-6GHz bands. However, there is very little information about the specifics of the modem and its peak throughput. If we go by the Pixel 7 product listing, it supports almost 22 5G bands, covering most of the NR frequency bands. Apart from that, it supports Bluetooth 5.2 and Wi-Fi 6E.

Moving to the Snapdragon 8+ Gen 1, it includes the in-house X65 5G modem, which offers a peak theoretical download speed of 10Gbps. In addition, the chipset brings support for Bluetooth 5.3 and LE standards. Finally, the A16 Bionic also features a discrete X65 5G modem from Qualcomm and supports Wi-Fi 6 and Bluetooth 5.3.

Overall, in terms of 5G and wireless connectivity, the Google Tensor G2 lags behind SD 8+ Gen 1 and A16 Bionic. Qualcomm is one of the leaders in the modem industry, and Samsung’s modems have not been able to catch up with the best in the industry. In fact, Samsung has decided that it’s only going to use Qualcomm’s X70 5G modem on the Galaxy S23 series, so you can catch the drift.

So that was our in-depth comparison between the Google Tensor G2, Snapdragon 8+ Gen 1, and A16 Bionic. Except in the CPU and modem department, we believe that the Google Tensor G2 is a middle-of-the-road chipset that features a power-efficient GPU, impressive TPU (AI + ML), and a powerful ISP. Now, it is time to test how well Google has optimized the phone to handle intensive tasks under sustained load and if there are any thermal throttling or heating issues.