Qualcomm's Snapdragon 808/810: 20nm High-End 64-bit SoCs with LTE Category 6/7 Support in 2015
by Anand Lal Shimpi on April 7, 2014 7:30 AM ESTToday Qualcomm is rounding out its 64-bit family with the Snapdragon 808 and 810. Like the previous 64-bit announcements (Snapdragon 410, 610 and 615), the 808 and 810 leverage ARM's own CPU IP in lieu of a Qualcomm designed microarchitecture. We'll finally hear about Qualcomm's own custom 64-bit architecture later this year, but it's clear that all 64-bit Snapdragon SoCs shipping in 2014 (and early 2015) will use ARM CPU IP.
While the 410, 610 and 615 all use ARM Cortex A53 cores (simply varying the number of cores and operating frequency), the 808 and 810 move to a big.LITTLE design with a combination of Cortex A53s and Cortex A57s. The latter is an evolution of the Cortex A15, offering anywhere from a 25 - 55% increase in IPC over the A15. The substantial increase in performance comes at around a 20% increase in power consumption at 28nm. Thankfully both the Snapdragon 808 and 810 will be built at 20nm, which should help offset some of the power increase.
Qualcomm's 64-bit Lineup | |||||||
Snapdragon 810 | Snapdragon 808 | Snapdragon 615 | Snapdragon 610 | Snapdragon 410 | |||
Internal Model Number | MSM8994 | MSM8992 | MSM8939 | MSM8936 | MSM8916 | ||
Manufacturing Process | 20nm | 20nm | 28nm LP | 28nm LP | 28nm LP | ||
CPU | 4 x ARM Cortex A57 + 4 x ARM Cortex A53 (big.LITTLE) | 2 x ARM Cortex A57 + 4 x ARM Cortex A53 (big.LITTLE) | 8 x ARM Cortex A53 | 4 x ARM Cortex A53 | 4 x ARM Cortex A53 | ||
ISA | 32/64-bit ARMv8-A | 32/64-bit ARMv8-A | 32/64-bit ARMv8-A | 32/64-bit ARMv8-A | 32/64-bit ARMv8-A | ||
GPU | Adreno 430 | Adreno 418 | Adreno 405 | Adreno 405 | Adreno 306 | ||
H.265 Decode | Yes | Yes | Yes | Yes | No | ||
H.265 Encode | Yes | No | No | No | No | ||
Memory Interface | 2 x 32-bit LPDDR4-1600 | 2 x 32-bit LPDDR3-933 | 2 x 32-bit LPDDR3-800 | 2 x 32-bit LPDDR3-800 | 2 x 32-bit LPDDR2/3-533 | ||
Integrated Modem | 9x35 core, LTE Category 6/7, DC-HSPA+, DS-DA | 9x35 core, LTE Category 6/7, DC-HSPA+, DS-DA | 9x25 core, LTE Category 4, DC-HSPA+, DS-DA | 9x25 core, LTE Category 4, DC-HSPA+, DS-DA | 9x25 core, LTE Category 4, DC-HSPA+, DS-DA | ||
Integrated WiFi | - | - | Qualcomm VIVE 802.11ac 1-stream | Qualcomm VIVE 802.11ac 1-stream | Qualcomm VIVE 802.11ac 1-stream | ||
eMMC Interface | 5.0 | 5.0 | 4.5 | 4.5 | 4.5 | ||
Camera ISP | 14-bit dual-ISP | 12-bit dual-ISP | ? | ? | ? | ||
Shipping in Devices | 1H 2015 | 1H 2015 | Q4 2014 | Q4 2014 | Q3 2014 |
The Snapdragon 808 features four Cortex A53s and two Cortex A57s, while the 810 moves to four of each. In both cases all six/eight cores can be active at once (Global Task Scheduling). The designs are divided into two discrete CPU clusters (one for the A53s and one for the A57s). Within a cluster all of the cores have to operate at the same frequency (a change from previous Snapdragon designs), but each cluster can operate at a different frequency (which makes sense given the different frequency targets for these two core types). Qualcomm isn't talking about cache sizes at this point, but I'm guessing we won't see anything as cool/exotic as a large shared cache between the two clusters. Although these are vanilla ARM designs, Qualcomm will be using its own optimized cells and libraries, which may translate into better power/performance compared to a truly off-the-shelf design.
The CPU is only one piece of the puzzle as the rest of the parts of these SoCs get upgraded as well. The Snapdragon 808 will use an Adreno 418 GPU, while the 810 gets an Adreno 430. I have no idea what either of those actually means in terms of architecture unfortunately (Qualcomm remains the sole tier 1 SoC vendor to refuse to publicly disclose meaningful architectural details about its GPUs). In terms of graphics performance, the Adreno 418 is apparently 20% faster than the Adreno 330, and the Adreno 430 is 30% faster than the Adreno 420 (100% faster in GPGPU performance). Note that the Adreno 420 itself is something like 40% faster than Adreno 330, which would make Adreno 430 over 80% faster than the Adreno 330 we have in Snapdragon 800/801 today.
Also on the video side: both SoCs boast dedicated HEVC/H.265 decode hardware. Only the Snapdragon 810 has a hardware HEVC encoder however. The 810 can support up to two 4Kx2K displays (1 x 60Hz + 1 x 30Hz), while the 808 supports a maximum primary display resolution of 2560 x 1600.
The 808/810 also feature upgraded ISPs, although once again details are limited. The 810 gets an upgraded 14-bit dual-ISP design, while the 808 (and below?) still use a 12-bit ISP. Qualcomm claims up to 1.2GPixels/s of throughput, putting ISP clock at 600MHz and offering a 20% increase in ISP throughput compared to the Snapdragon 805.
The Snapdragon 808 features a 64-bit wide LPDDR3-933 interface (1866MHz data rate, 15GB/s memory bandwidth). The 810 on the other hand features a 64-bit wide LPDDR4-1600 interface (3200MHz data rate, 25.6GB/s memory bandwidth). The difference in memory interface prevents the 808 and 810 from being pin-compatible. Despite the similarities otherwise, the 808 and 810 are two distinct pieces of silicon - the 808 isn't a harvested 810.
Both SoCs have a MDM9x35 derived LTE Category 6/7 modem. The SoCs feature essentially the same modem core as a 9x35 discrete modem, but with one exception: Qualcomm enabled support for 3 carrier aggregation LTE (up from 2). The discrete 9x35 modem implementation can aggregate up to two 20MHz LTE carriers in order to reach Cat 6 LTE's 300Mbps peak download rate. The 808/810, on the other hand, can combine up to three 20MHz LTE carriers (although you'll likely see 3x CA used with narrower channels, e.g. 20MHz + 5MHz + 5MHz or 20MHz + 10MHz + 10MHz).
Enabling 3x LTE CA requires two RF transceiver front ends: Qualcomm's WTR3925 and WTR3905. The WTR3925 is a single chip, 2x CA RF transceiver and you need the WTR3905 to add support for combining another carrier. Category 7 LTE is also supported by the hardware (100Mbps uplink), however due to operator readiness Qualcomm will be promoting the design primarily as category 6.
There's no integrated WiFi in either SoC. Qualcomm expects anyone implementing one of these designs to want to opt for a 2-stream, discrete solution such as the QCA6174.
Qualcomm refers to both designs as "multi-billion transistor" chips. I really hope we'll get to the point of actual disclosure of things like die sizes and transistor counts sooner rather than later (the die shot above is inaccurate).
The Snapdragon 808 is going to arrive as a successor to the 800/801, while the 810 sits above it in the stack (with a cost structure similar to the 805). We'll see some "advanced packaging" used in these designs. Both will be available in a PoP configuration, supporting up to 4GB of RAM in a stack. Based on everything above, it's safe to say that these designs are going to be a substantial upgrade over what Qualcomm offers today.
Unlike the rest of the 64-bit Snapdragon family, the 808 and 810 likely won't show up in devices until the first half of 2015 (410 devices will arrive in Q3 2014, while 610/615 will hit in Q4). The 810 will come first (and show up roughly two quarters after the Snapdragon 805, which will show up two quarters after the recently released 801). The 808 will follow shortly thereafter. This likely means we won't see Qualcomm's own 64-bit CPU microarchitecture show up in products until the second half of next year.
With the Snapdragon 808 and 810, Qualcomm rounds out almost all of its 64-bit lineup. The sole exception is the 200 series, but my guess is the pressure to move to 64-bit isn't quite as high down there.
What's interesting to me is just how quickly Qualcomm has shifted from not having any 64-bit silicon on its roadmap to a nearly complete product stack. Qualcomm appeared to stumble a bit after Apple's unexpected 64-bit Cyclone announcement last fall. Leaked roadmaps pointed to a 32-bit only future in 2014 prior to the introduction of Apple's A7. By the end of 2013 however, Qualcomm had quickly added its first 64-bit ARMv8 based SoC to the roadmap (Snapdragon 410). Now here we are, just over six months since the release of iPhone 5s and Qualcomm's 64-bit product stack seems complete. It'll still be roughly a year before all of these products are shipping, but if this was indeed an unexpected detour I really think the big story is just how quickly Qualcomm can move.
I don't know of any other silicon player that can move and ship this quickly. Whatever efficiencies and discipline Qualcomm has internally, I feel like that's the bigger threat to competing SoC vendors, not the modem IP.
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CiccioB - Monday, April 7, 2014 - link
I can't understand how difficult is to make a "quick shift" of the roadmap when you are using ready on-the-shelf IP like Cortex A-57/53 while the rest of the SoC is the same as for previous projects you have thrown away.aruisdante - Monday, April 7, 2014 - link
If you think that changing the entire product roadmap for two years for an enormous, international multi-billion dollar company is 'simple', then you probably don't have much experience with big-business.CiccioB - Monday, April 7, 2014 - link
Actually this "quick shift" is going to require about 1.5 year on paper.Qualcomm is going to use ARM IP for thier SoC cores, so past wrong choices that understimated 64 bit marketing power is an economic problem in those 32bit 28nm investments that will never see the light in, not really a time related one, as 64 bit 20nm ARM IP is aready available.
The shocking impact is to see Qualcomm not ready for the new 64 bit step after having dominated the 32bit market for some years now. And it is not only Apple (which races in its own market) their problem: nvidia and Samsung already announced their 64 bit architetures while Mediatek and other chinese/tawainese producers already have 64 bit SoC ready.
I already forsee that Qualcomm could not continue developing an in house custom architecture for main stream market when ARM architecture would have become too complex. I think ARM v8 64 bit architecture mark the sign. Qualcomm will probably create a custom 64 bit architecture for SoC destined to other (server?) market but it will take time (quite a lot) and competitors will not wait for them. 64 bit (marketing speaking) is now, and everyone is trying to catch the passing train.
mrdude - Monday, April 7, 2014 - link
One of the biggest benefits the ARM ecosystem has is exactly that point: being able to react and adapt quickly by utilizing 'stock' designs with a significantly lower time-to-market. This model extends to the fab side as well.Qualcomm likely (and perhaps correctly) didn't see a need to push for 64-bit designs so early. Apple caught them off guard and Qualcomm had to react quickly. If this were to hypothetically happen on x86, we'd be waiting another 3-4 years to see the big rival push out a competing silicon.
Hopefully Qualcomm has been working quietly on an ARMv8-a design. I'm eager to see what they can come up with.
blanarahul - Monday, April 7, 2014 - link
First 20 NM chips??mikegonzalez2k - Tuesday, May 20, 2014 - link
The purpose of a roadmap is the development of the tasks needed for the critical path. Changing those tasks completely modifies the critical path because other tasks may be dependent on the tasks which were removed from that path.Here is a basic example of the Critical Path Method
https://www.youtube.com/watch?v=DdDzybQ_9vM
SydneyBlue120d - Monday, April 7, 2014 - link
This means the rumors of a Nexus 6 based on LG G3, running the 805 may be true... I really hoped to have HEVC on board acquisition for Nexus 6, but this will not be the case... Can You make a comparison with Intel Tablet/Smartphon SOC 64 bit proposition ? Thanks a lot :)antef - Monday, April 7, 2014 - link
Not sure why people keep saying "Nexus 6". They name them by screen size, and I highly their next phone will have a 6" screen.antef - Monday, April 7, 2014 - link
should be "highly doubt"Aenean144 - Monday, April 7, 2014 - link
Just to be pedantic, Google names their phone whatever the hell they want. There's no correlation there. Prior to the Nexus 5, was the Nexus 4, and I'm pretty sure it's stretching it to say they called it "Nexus 4" because of its screen size. It's convenient to think of the number as the screen size, until it isn't.And you already know why people are calling it Nexus 6. It's just a convenient way to indicate they are talking about the next Nexus phone. Not sure why people just don't say the 2014 Nexus though.