OMAP (Open Multimedia Applications Platform) is a family ofimage/video processors that was developed byTexas Instruments. They are proprietarysystem on chips (SoCs) for portable and mobilemultimediaapplications. OMAP devices generally include a general-purposeARM architecture processor core plus one or more specializedco-processors. Earlier OMAP variants commonly featured a variant of theTexas Instruments TMS320 seriesdigital signal processor.
The platform was created after December 12, 2002, asSTMicroelectronics and Texas Instruments jointly announced an initiative forOpen Mobile Application Processor Interfaces (OMAPI) intended to be used with2.5 and3Gmobile phones, that were going to be produced during 2003.[1] (This was later merged into a larger initiative and renamed theMIPI Alliance.) The OMAP was Texas Instruments' implementation of this standard. (The STMicroelectronics implementation was namedNomadik.)
OMAP enjoyed some success in the smartphone and tablet market until 2011 when it lost ground toQualcomm Snapdragon.[2] On September 26, 2012, Texas Instruments announced that they would wind down their operations in smartphone and tablet oriented chips and focus on embedded platforms instead.[3] On November 14, 2012, Texas Instruments announced they would cut 1,700 jobs due to their shift from mobile to embedded platforms.[4] The last OMAP5 chips were released in Q2 2013.
The OMAP family consists of three product groups classified by performance and intended application:
Further, two main distribution channels exist, and not all parts are available in both channels. The genesis of the OMAP product line is from partnership with cell phone vendors, and the main distribution channel involves sales directly to suchwireless handset vendors. Parts developed to suit evolving cell phone requirements are flexible and powerful enough to support sales through less specializedcatalog channels; some OMAP 1 parts, and many OMAP 3 parts, have catalog versions with different sales and support models. Parts that are obsolete from the perspective of handset vendors may still be needed to support products developed using catalog parts and distributor-based inventory management.
These are parts originally intended for use as application processors insmartphones, with processors powerful enough to run significantoperating systems (such asLinux,FreeBSD,Android orSymbian), support connectivity to personal computers, and support various audio and video applications.
The OMAP 1 family started with a TI-enhancedARM925 core (ARM925T), and then changed to a standard ARM926 core. It included many variants, most easily distinguished according to manufacturing technology (130 nm except for the OMAP171x series), CPU, peripheral set, and distribution channel (direct to large handset vendors, or through catalog-based distributors). In March 2009, the OMAP1710 family chips are still available to handset vendors.
Products using OMAP 1 processors include hundreds of cell phone models, and theNokia 770Internet tablets.
These parts were only marketed to handset vendors. Products using these include both Internet tablets andmobile phones:
The 3rd generation OMAP, the OMAP 3[6] is broken into 3 distinct groups: the OMAP34x, the OMAP35x, and the OMAP36x. OMAP34x and OMAP36x are distributed directly to large handset (such as cell phone) manufacturers. OMAP35x is a variant of OMAP34x intended for catalog distribution channels. The OMAP36x is a45 nm version of the65 nm OMAP34x with higher clock speed.[7]
The OMAP 3611 found in devices like the Bookeen's Cybook Odyssey is a licensed crippled version of the OMAP 3621, both are the same silicon (as marking are the same) but officially the 3611 was sold to be only able to drive e-Ink screen and does not have access to IVA & DSP.
The video technology in the higher end OMAP 3 parts is derived in part from theDaVinci product line, which first packaged higher end C64x+ DSPs and image processing controllers with ARM9 processors last seen in the older OMAP 1 generation or ARM Cortex-A8.[8]
Not highlighted in the list below is that each OMAP 3 SoC has an "Image, Video, Audio" (IVA2) accelerator. These units do not all have the same capabilities. Most devices support 12 megapixel camera images, though some support 5 or 3 megapixels. Some support HD imaging.
| Model number | Fab | CPU | Frq (MHz) | GPU | DSP | HSA-features | Utilizing devices |
|---|---|---|---|---|---|---|---|
| OMAP3410 | 65 nm | Cortex-A8 | 600 | PowerVR SGX530 | Unknown | Unknown | List |
| OMAP3420 | |||||||
| OMAP3430 | TMS320C64x+ | ||||||
| OMAP3440 | 800 | Unknown | List
| ||||
| OMAP3503 | 600 | - | |||||
| OMAP3515 | 600 | PowerVR SGX530 | |||||
| OMAP3525 | 600 | - | |||||
| OMAP3530 | 720 MHz | PowerVR SGX530 | TMS320C64x+[11] | List
| |||
| OMAP3611 | 45 nm | 800 | List
| ||||
| OMAP3621 | 800 | ||||||
| OMAP3622 | 1000 | ||||||
| OMAP3630 | 600 MHz~1.2 GHz | Unknown | List
| ||||
| OMAP3640 | 1.2 GHz |
The OMAP 4 line consists of the OMAP 4430, OMAP 4460 (formerly named 4440),[20] and OMAP 4470. The 4th generation OMAPs have adual-coreARM Cortex-A9 CPU with two ARMCortex-M3 cores, as part of the"Ducati" sub-system[21] for off-loading low-level tasks.[22][23][24] The OMAP 4430 was the SoC used inGoogle Glass.[25]
OMAP 4 uses ARM Cortex-A9's with ARM's SIMD engine (Media Processing Engine, aka NEON) which in some cases may have a significant performance advantage overNvidia Tegra 2's ARM Cortex-A9s with non-vector floating point units.[26] It also uses a dual-channel LPDDR2 memory controller compared to Nvidia Tegra 2's single-channel memory controller.
All OMAP 4 processors come with an IVA3 multimedia hardware accelerator with a programmable DSP that enables 1080p Full HD and multi-standard video encoding and decoding.[27][28][29][30]
The 4430 and 4460 use a PowerVR SGX540graphics processing unit (GPU). The 4430's GPU runs at a clock frequency of 304 Mhz, and the 4460's GPU runs at 384 MHz.[31]
The 4470 has a PowerVR SGX544 GPU that supports DirectX 9 that enables it for use inWindows 8. It also has a dedicated 2D graphics core for increased power efficiency up to 50-90%.[32]
The 5th generation OMAP, OMAP 5SoC uses a dual-coreARM Cortex-A15 CPU with two additionalCortex-M4 cores to offload the A15s in less computationally intensive tasks to increase power efficiency, two PowerVR SGX544MP graphics cores and a dedicated TI 2D BitBlt graphics accelerator, a multi-pipe display sub-system and a signal processor.[44] They respectively support 24 and 20 megapixel cameras for front and rear 3D HD video recording. The chip also supports up to 8 GB of dual channel LPDDR2/DDR3 memory, output to four HD 3D displays and 3D HDMI 1.4 video output. OMAP 5 also includes three USB 2.0 ports, one lowspeed USB 3.0 OTG port and a SATA 2.0 controller.
| Model number | Fab | CPU | Frq | GPU | Frq | DSP | Memory technology | Availability | Utilizing devices |
|---|---|---|---|---|---|---|---|---|---|
| OMAP5430 | 28 nm | Cortex-A15 (dual-core)[45] and Cortex-M4 (dual-core) | 1.5, 1.7 GHz | PowerVR SGX544MP2[46] + dedicated TI 2D BitBlt graphics accelerator | 532 MHz | "Tesla" (C64T) | 32-bit dual-channel 532 MHz LPDDR2 (8.5 GB/sec)[47] | Q2 2013 | List
|
| OMAP5432 | 1.5, 1.7 GHz | 532 MHz | 32-bit dual-channel 532 MHz DDR3 (8.5 GB/sec)[47] | Q2 2013 | List
|
These are marketed only to handset manufacturers. They are intended to be highly integrated, low cost chips for consumer products. The OMAP-DM series are intended to be used as digital media coprocessors for mobile devices with high megapixel digital still and video cameras. These OMAP-DM chips incorporate both anARM processor and anImage Signal Processor (ISP) to accelerate processing of camera images.
These are marketed only to handset manufacturers. Many of the newer versions are highly integrated for use in very low cost cell phones.
The OMAP L-1x parts are marketed only through catalog channels, and have a different technological heritage than the other OMAP parts. Rather than deriving directly from cell phone product lines, they grew from the video-orientedDaVinci product line by removing the video-specific features while using upgraded DaVinci peripherals. A notable feature is use of afloating point DSP, instead of the more customary fixed point one.
TheHawkboard uses the OMAP-L138
Manymobile phones released during early 21st century have used OMAP SoCs, including theNokia 3230, N9, N90, N91, N92, N95, N82, E61, E62, E63 and E90 mobile phones, as well as the Nokia 770, N800, N810 andN900Internet tablets,Motorola Droid,Droid X, andDroid 2, and some early Samsung Galaxy devices, like Samsung Galaxy Tab 2 7.0 and Galaxy S II variant GT-I9100G.
The OMAP3430 is used in thePalm Pre,Pandora, andTouch Book. Other devices that use OMAP processors include Sony Ericsson'sSatio (Idou) andVivaz, most Samsung phones running Symbian (includingOmnia HD), theNook Color, someArchos tablets (such as Archos 80 gen 9 and Archos 101 gen 9),Kindle Fire HD,Blackberry Playbook,Kobo Arc, and B&NNook HD.
Some all-in-one smart displays use OMAP 4 SoCs, including the Viewsonic VSD220, which uses an OMAP 4430.
OMAP SoCs are also used as the basis for a number of hobbyist, prototyping and evaluation boards, such as theBeagleBoard,PandaBoard, OMAP3 Board,Gumstix and Presonus digital mixing boards
Motorola MOTOTRBO 2. generation radios use the OMAP-L132 or OMAP-L138 secure CPU.
The OMAP 5 processor leverages two ARM Cortex-A15 MPCores [...] [It] also includes two ARM Cortex-M4 processors [...]