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			{{short description\|Industry standard}}
	{{multiple issues\|
	{{advert\|date=January 2016}}
	{{refimprove\|date=January 2016}}
	}}

	{{Infobox connector		{{Infobox connector
	\| logo = ]		\| logo = ]
	\| name = ~~MHL (~~Mobile High-Definition Link)		\| name = Mobile High-Definition Link (MHL)
	\| type = Digital audio/video/data connector		\| type = Digital audio/video/data connector
	\| designer =		\| designer =
Line 19:		Line 15:
	\| ]		\| ]
	}}		}}
	\| design_date = ~~January~~ ~~2008~~		\| design_date = {{start date and age\|June 2010}}
	\| hotplug = Yes		\| hotplug = Yes
	\| external = Yes		\| external = Yes
	\|num_pins= MHL 1, 2, & 3 (5),<ref>{{cite web\|title=Mobile High-Definition Link (MHL) - Technology White Paper\|url=http://www.mhltech.org/docs/MHL3Whitepaper.pdf\|publisher=MHL\|~~accessdate~~=7 February 2017\|date=October 2013}}</ref> superMHL (~~5–32~~)<ref>{{cite web\|title=superMHL Specification - White Paper\|url=http://www.mhltech.org/docs/superMHL_WhitePaper.pdf\|publisher=MHL\|~~accessdate~~=7 February 2017\|date=September 2015}}</ref>}}		\|num_pins= MHL 1, 2, & 3 (5),<ref name="MHL3Whitepaper">{{cite web\|title=Mobile High-Definition Link (MHL) - Technology White Paper\|url=http://www.mhltech.org/docs/MHL3Whitepaper.pdf\|publisher=MHL\|access-date=7 February 2017\|date=October 2013\|archive-url=https://web.archive.org/web/20170208034023/http://www.mhltech.org/docs/MHL3Whitepaper.pdf\|archive-date=8 February 2017\|url-status=dead}}</ref> <br />superMHL (5/24/32)<ref name="superMHL_Whitepaper">{{cite web\|title=superMHL Specification - White Paper\|url=http://www.mhltech.org/docs/superMHL_WhitePaper.pdf\|publisher=MHL\|access-date=7 February 2017\|date=September 2015\|archive-url=https://web.archive.org/web/20170208034550/http://www.mhltech.org/docs/superMHL_WhitePaper.pdf\|archive-date=8 February 2017\|url-status=dead}}</ref>}}

	'''Mobile High-Definition Link''' ('''MHL''') is an ] for a mobile audio/video interface that allows the connection of ]s, tablets, and other portable ] ~~(CE)~~ devices to ]s (HDTVs) ~~and~~ audio receivers~~. MHL-enabled products include adapters~~, ~~automotive~~ ~~accessories,~~ AV ~~receivers,~~ ~~Blu-ray~~ ~~Disc~~ ~~players,~~ ~~cables,~~ ~~DTVs,~~ ~~media~~ ~~sticks,~~ ~~monitors~~, ~~projectors,~~ ~~smartphones,~~ ~~tablets~~, ~~TV accessories~~ and ~~more.~~ ~~MHL~~ is a ] ~~made~~ up of ~~major~~ ~~companies~~ in ~~the~~ ~~mobile~~ ~~and~~ CE ~~industries,~~ ~~including~~ ], ~~], ], ]~~ ~~and~~ ].		'''Mobile High-Definition Link''' ('''MHL''') is an ] for a mobile audio/video interface that allows the connection of ]s, tablets, and other portable ] devices to ]s (HDTVs), audio receivers, and projectors. The standard was designed to share existing mobile device connectors, such as ], and avoid the need to add video connectors on devices with limited space for them.<ref>{{cite web\|title=Mobile High-Definition Link (MHL™) Technology\|url=http://www.siliconimage.com/technologies/index.aspx?Page=7&Section=1\|website=Silicon Image\|archive-url=https://web.archive.org/web/20100110122613/http://www.siliconimage.com/technologies/index.aspx?Page=7&Section=1\|archive-date=10 January 2010}}</ref>

			MHL connects to display devices either directly through special ] inputs that are MHL-enabled, or indirectly through standard HDMI inputs using MHL-to-HDMI adapters. MHL was developed by a ] of five companies: ], ], ], ] and ].

	== History ==		== History ==
	Silicon Image, one of the founding companies of the ] standard, originally demonstrated a mobile ] at the January 2008 ] (CES), based on its ] (TMDS) technology.<ref name="~~EETimes~~">{{cite news \| url=http://www.eetimes.com/electronics-products/logic-interfaces-products/4101084/HDMI-plugs-into-cameras-cellphones \| title=HDMI plugs into cameras, cellphones \| work=EETimes.com \| date=January 8, 2008 \| ~~accessdate~~=2010-04-14}}</ref> This interface was termed "Mobile High Definition Link" at the time of the demonstration, and is a direct precursor of the implementation announced by the MHL Consortium. The company is quoted as saying it did not ship that original technology in any volume, but used it as a way to get a ] started.<ref name="~~EETimesApr10~~">{{cite news \| url=http://www.eetimes.com/electronics-news/4088597/Consortium-backs-mobile-interface-for-high-def-video \| title=Consortium backs mobile interface for high def video ~~\| publisher=EE Times~~ \| work=EETimes.com \| date=April 14, 2010 \| ~~accessdate~~=2010-04-14}}</ref>		Silicon Image, one of the founding companies of the ] standard, originally demonstrated a mobile ] at the January 2008 ] (CES), based on its ] (TMDS) technology.<ref name="EETimesJan2008">{{cite news \| url=http://www.eetimes.com/electronics-products/logic-interfaces-products/4101084/HDMI-plugs-into-cameras-cellphones \| title=HDMI plugs into cameras, cellphones \| work=EETimes.com \| date=January 8, 2008 \| access-date=2010-04-14}}</ref><ref name="EETimesJuly2008">{{cite news\|title=Silicon Image angles to extend its HDMI success to handsets\|url=http://www.eetimes.com/document.asp?doc_id=1168914\|work=EETimes.com\|date=14 July 2008 \|access-date=2010-04-14}}</ref> This interface was termed "Mobile High Definition Link" at the time of the demonstration, and is a direct precursor of the implementation announced by the MHL Consortium. The company is quoted as saying it did not ship that original technology in any volume, but used it as a way to get a ] started.<ref name="EETimesApr2010">{{cite news \| url=http://www.eetimes.com/electronics-news/4088597/Consortium-backs-mobile-interface-for-high-def-video \| title=Consortium backs mobile interface for high def video \| work=EETimes.com \| date=April 14, 2010 \| access-date=2010-04-14}}</ref>

	The working group was announced in September 2009,<ref>{{cite press release \| url=http://www.siliconimage.com/news/releasedetails.aspx?id=591 \| title=Leading Companies Form Mobile High-Definition Interface Working Group to Drive Industry Standard for Mobile Wired Connectivity \| publisher=Silicon Image \| date=September 28, 2009 \| ~~accessdate~~=2009-09-30 \| ~~archiveurl~~=https://web.archive.org/web/20110716071304/http://www.siliconimage.com/news/releasedetails.aspx?id=591 \| ~~archivedate~~=2011-07-16}}</ref> and the MHL Consortium founded in April 2010 by ], ], ], ] and ]. The MHL specification version 1.0 was released in June 2010 and May 2011 marked the first retail availability of MHL-enabled products.		The working group was announced in September 2009,<ref>{{cite press release \| url=http://www.siliconimage.com/news/releasedetails.aspx?id=591 \| title=Leading Companies Form Mobile High-Definition Interface Working Group to Drive Industry Standard for Mobile Wired Connectivity \| publisher=Silicon Image \| date=September 28, 2009 \| access-date=2009-09-30 \| archive-url=https://web.archive.org/web/20110716071304/http://www.siliconimage.com/news/releasedetails.aspx?id=591 \| archive-date=2011-07-16}}</ref> and the MHL Consortium founded in April 2010 by ], ], ], ] and ]. The MHL specification version 1.0 was released in June 2010,<ref>{{cite press release \|title=MHL 1.0 Specification and Adopter Agreement Now Available \|publisher=MHL, LLC \|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=2147495449 \|date=June 30, 2010 \|access-date=2010-06-30 \|archive-url=https://web.archive.org/web/20151027021141/http://www.mhltech.org/PressReleaseDetail.aspx?id=2147495449 \|archive-date=October 27, 2015 \|url-status=dead }}</ref> and the Compliance Test Specification (CTS) was released in December 2010.<ref>{{cite press release \|title=MHL Consortium Releases Compliance Test Specification to Growing Adopter Base \|publisher=MHL, LLC \|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=71 \|date=December 21, 2010 \|access-date=2010-12-22}}</ref> May 2011 marked the first retail availability of MHL-enabled products.<ref>{{cite press release \|title=MHL Technology Reaches Major Milestone with the First MHL-Enabled Smartphones Now in Mass Production \|publisher=MHL, LLC \|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=59 \|date=May 16, 2011 \|access-date=2017-04-25}}</ref>

			The first mobile device to feature the MHL standard was the ], announced at the 2011 ].<ref name="MWC2011_interview">{{cite news \|title=MHL High-definition Link\|publisher=YouTube \|url=https://www.youtube.com/watch?v=ZtwTcnR0hqA \|date=February 15, 2011 \|access-date=2011-02-15}}</ref><ref>{{cite news\|title=Samsung Galaxy S II first with MHL port for dual-purpose USB or HDMI out (video)\|url=https://www.engadget.com/2011/02/23/samsung-galaxy-s-ii-first-with-mhl-port-for-dual-purpose-usb-or/\|access-date=25 April 2017\|work=Engadget\|date=23 February 2011}}</ref>
	An abridged version of the specification was made available for download on April 14, 2010.<ref>{{cite news \|title=Adopter Information \|publisher=MHL, LLC \|url=http://www.mhlconsortium.org/adopter.aspx \|date=June 30, 2010 \|accessdate=2010-06-30}}</ref>
			MHL announced in 2014 that more than half a billion MHL-capable products had been shipped since the standard was created.<ref name="HalfBillionPR">{{cite press release \| url=http://mhlconsortium.org/PressReleaseDetail.aspx?id=2147497229 \| title=MHL Consortium Announces More Than Half A Billion MHL Products Have Shipped Worldwide \| publisher=MHL Consortium \| date=24 February 2014 \| access-date=9 January 2016}}</ref>
	MHL specification version 1.0 was released in June 2010.<ref>{{cite news \|title=MHL 1.0 SPECIFICATION AND ADOPTER AGREEMENT NOW AVAILABLE \|publisher=MHL, LLC \|url=http://www.mhlconsortium.org/news/release.aspx#Specification1 \|date=June 30, 2010 \|accessdate=2010-06-30}}</ref>
	The Compliance Test Specification (CTS) was announced on December 21, 2010.<ref>{{cite news \|title=MHL CONSORTIUM RELEASES COMPLIANCE TEST SPECIFICATION TO GROWING ADOPTER BASE \|publisher=MHL, LLC \|url=http://www.mhlconsortium.org/news/press_release.aspx?prid=4 \|date=December 21, 2010 \|accessdate=2010-12-22}}</ref>

	MHL announced in 2014 that more than half a billion MHL-capable products had been shipped since the standard was created.<ref name="HalfBillionPR">{{cite press release \| url=http://mhlconsortium.org/PressReleaseDetail.aspx?id=2147497229 \| title=MHL Consortium Announces More Than Half A Billion MHL Products Have Shipped Worldwide \| publisher=MHL Consortium \| date=24 February 2014 \| accessdate=9 January 2016}}</ref>

	== Overview ==		== Overview ==
			] ID (pin 4), and the HDMI Hot Plug Detect (pin 19), while the pins for power & ground match their original assignment for both.\|upright=1.8]]
	{{prose\|section\|date=January 2016}}
	MHL was originally intended for mobile devices such as smartphones and tablets.

			MHL is an adaptation of ] intended for mobile devices such as smartphones and tablets.<ref name="mhl-synopsys">{{cite web\|author1=Manmeet Walia\|title=MHL: The New Mobile-to-TV Protocol\|url=https://www.synopsys.com/designware-ip/newsletters/technical-bulletin/mhl-protocol.html\|website=Synopsys.com\|access-date=15 February 2017\|language=en}}</ref> Unlike ], which is compatible with HDMI using only passive cables and adapters, MHL requires that the HDMI socket be MHL-enabled. (To deliver an MHL signal to a non-MHL HDMI socket, one can use an adapter device that receives the signal on an MHL-enabled socket, converts it to HDMI, and transmits the HDMI signal to the non-MHL socket). It has several aspects in common with HDMI, such as the ability to carry ] ] encrypted ], eight-channel ], and control remote devices with ] (CEC).
	* ] and eight-channel ].
	* Encrypted video and audio via ] (HDCP).
	* ] (TMDS) for video, audio, and auxiliary data.
	* 5-volt DC power on the cable.
	* ] control of remote devices.
	To better accommodate the needs of mobile devices, MHL differs from HDMI as follows.
	* Five wires in place of HDMI's nineteen, namely ground, power, control, and a differential pair for data. This permits a much lighter cable and a much smaller connector on the mobile device.
	* Whereas HDMI uses the power line to provide 5 volts from the source at 50 mA (0.25 W) for the purpose of awakening a sleeping sink, MHL uses it to provide that voltage from the sink at 900 mA (4.5 W) to maintain the state of charge of the source. This allows a mobile device with only one port for both charging and MHL to operate indefinitely without exhausting the battery, provided 4.5 W is sufficient. Devices needing more power from the port used for MHL may not be suitable candidates for MHL 2.0; MHL 3.0 raises the power requirement to 2 A (10 W).
	* Although MHL ports can be dedicated to MHL alone, the standard is designed to permit port sharing with the most commonly used ports.
	* A typical MHL source will be shared with USB 2.0 on a standard 5-pin ] receptacle, which switches from USB to MHL when it recognizes an MHL-qualified sink detected on the control wire.
	* A typical MHL sink will be shared with HDMI on a standard 19-pin HDMI receptacle. The standard uses the same pins for power (pin 18) and ground (pins 5, 11, and 17), HDMI's Hot Plug detect (pin 19) for MHL control, and HDMI's Data0 channel (pins 7 and 9) for MHL's data.
	* Whereas HDMI transmits the three bytes of a pixel in parallel over three physically separate differential pairs along with a fourth pair for a clock, with a separate ground for each pair (pins 1-12), MHL transmits them sequentially over one pair (7 and 9), with the clock added in as a common mode signal to the differential signal. The receiver then has both differential and common mode detection circuits.<ref name="mhl_keysight>{{cite web\|title=Enable New Generation of Display Interface: Introducing MHL 3.2\|url=http://www.keysight.com/upload/cmc_upload/All/D_suit_8-11.pdf?&cc=eng&lc=eng\|publisher=Keysight Technologies\|accessdate=15 February 2017\|pages=21-33}}</ref> In MHL 3 and superMHL the clock signal is instead carried separately on an extended CBUS, renamed the enhanced control bus (eCBUS).
	* Whereas HDMI uses three wires to cater for ] (13), and ] (15 and 16), MHL controls these functions with a single wire (CBUS).
	*In normal mode MHL supplies the same 24 bit color signal as HDMI, at a pixel clock rate of up to 75 MHz for MHL 2.0, sufficient for ] and ]. Each of the three bytes is in a 10-bit frame whence at 75 MHz the data channel operates at 2.25 Gbit/s.<ref name="mhl-synopsys">{{cite web\|author1=Manmeet Walia\|title=MHL: The New Mobile-to-TV Protocol\|url=https://www.synopsys.com/designware-ip/newsletters/technical-bulletin/mhl-protocol.html\|website=Synopsys.com\|accessdate=15 February 2017\|language=en}}</ref><ref name="technical-overview_rohdeschwarz">{{cite web\|title=MHL (Mobile High-Definition Link) Technical overview\|url=https://cdn.rohde-schwarz.com/pws/dl_downloads/dl_common_library/dl_brochures_and_datasheets/pdf_1/MHL_po_en_folded_3606-6792-82_v0400.pdf\|publisher=Rohde & Schwarz\|accessdate=15 February 2017}}</ref>
	*MHL 2.0 caters for ] with a PackedPixel mode utilizing only the first two of HDMI's three channels. This shrinks each pixel to 16 bits (using YCbCr 4:2:2 ]) carried in two 10-bit frames. The pixel clock is doubled to 150 MHz and the data channel then operates at 3 Gbit/s.<ref name="mhl-synopsys"/><ref name="technical-overview_rohdeschwarz"/>
	*MHL's serial signaling makes it incompatible with the three-channel parallel signaling of HDMI and DVI. Hence both ends of an MHL channel must implement the standard in full. In particular an MHL source cannot drive an ordinary HDMI or DVI display, though this limitation is easily overcome with an MHL ] converting MHL to HDMI. An MHL source must be realized in hardware as the typical 5-pin USB 2.0 port on mobile devices is much too slow at 480 Mbit/s for a software-only implementation.

			There are a total of five pins used in MHL rather than the 19 used in HDMI, namely: a differential pair for data, a bi-directional control channel (CBUS), power charging supply, and ground. This permits a much lighter cable and a much smaller connector on the mobile device, as a typical MHL source will be shared with USB 2.0 on a standard 5-pin ] receptacle.<ref name="MHL3Whitepaper"/> (Although MHL ports can be dedicated to MHL alone, the standard is designed to permit port sharing with the most commonly used ports.) The USB port switches from USB to MHL when it recognizes an MHL-qualified sink (e.g., a TV) detected on the control wire. A typical MHL sink will be shared with HDMI on a standard 19-pin HDMI receptacle.
	== Versions ==

			Because the same five-pin Micro-USB port is also typically used for charging the device, the sink is required to provide power to maintain the state of charge (or even recharge) while it is being used (although this is dependent on the power available being sufficient e.g., MHL 2 & 3 provide a minimum of 4.5 W / 900 mA, while superMHL can provide up to 40 W). The use of the power line in this way differs from HDMI, which expects the source to provide 55 mA for the purpose of reading the ] of a display.<ref name="hdmi.org">{{cite web\|url=http://www.hdmi.org/learningcenter/kb.aspx?c=13#42\|title=HDMI Resources: Knowledge Base\|website=hdmi.org\|access-date=14 April 2017\|archive-date=25 May 2015\|archive-url=https://web.archive.org/web/20150525040442/http://www.hdmi.org/learningcenter/kb.aspx?c=13#42\|url-status=dead}}</ref>
	=== MHL 1 and MHL 2 ===
	* The TV provides power to the connected device (5 V DC/500 mA with MHL 1.0, 5 V DC/900 mA with MHL 2.0).
	* Uses a single, thin cable to connect the mobile device to the TV.
	* The TV remote will control the connected device with guaranteed mixed manufacturer interoperability ].<ref name="MWC2011_interview">{{cite news \|title=MHL High-definition Link\|publisher=YouTube \|url=https://www.youtube.com/watch?v=ZtwTcnR0hqA \|date=February 15, 2011 \|accessdate=2011-02-15}}</ref> (Also see Silicon Image's press release about MHL on December 14, 2010). Note: The built-in Remote Control Protocol (RCP) function allows you to use the ] of the TV to operate the MHL mobile device through TV’s ] (CEC) function.
	* ] uncompressed HD video.
	* 8 channel uncompressed audio (e.g., ]).
	* Supports ] (HDCP).
	* MHL is connection agnostic (i.e., not tied to a specific type of hardware connector). The first implementations used the 5-pin MHL-USB connector described below. Other proprietary and custom connections are also allowed.

			Because of to the low pin count of MHL versus HDMI, the functions that are carried on separate dedicated pins on HDMI, namely: the ] (DDC) (pins 15 & 16) and CEC (pin 13) are instead carried on the bi-directional control bus (CBUS). The CBUS both emulates the function of the DDC bus and also carries an MHL sideband channel (MSC), which emulates the CEC bus function, and allows a TV remote to control the media player on a phone with its Remote Control Protocol (RCP).
	=== MHL 3 ===
	On August 20, 2013, MHL announced its 3 specification to address the latest consumer requirements for connecting a mobile device to displays, marking major advancements in the areas of audio and video transmission over an MHL link. The first devices to include the specification are the ] and the ]. At Mobile World Congress 2014 ] demoed MHL 3 powered by its SiI8620 transmitter chip. Features of the MHL 3.0 specification include:

			=== Bandwidth ===
	* 4K (Ultra HD): Support of 4K formats up to 3840 × 2160 at 30 Hz
	* Simultaneous high-speed data channel
	* Improved Remote Control Protocol (RCP) with new commands
	* HID support for peripherals such as a touch screen, keyboard and mouse
	* Higher power charging up to 10 W
	* Backward compatible with MHL 1 and MHL 2
	* Latest ] 2.2 content protection
	* Enhanced 7.1 surround sound with Dolby ] and ]
	* Connector agnostic – uses as few as five pins
	* Support for simultaneous multiple displays

			MHL uses the same ] (TMDS) as HDMI to carry video, audio, and auxiliary data. However, MHL differs from HDMI in that there is only one ] to carry the TMDS data lane, compared to HDMI's four (three data lanes, plus the clock). Therefore these three logical data channels are instead ] into the single physical MHL data lane (i.e., with the logical channels sent sequentially), and the clock signal carried as a common mode signal of this pair.<ref name="mhl_keysight">{{cite web\|title=Enable New Generation of Display Interface: Introducing MHL 3.2\|url=http://www.keysight.com/upload/cmc_upload/All/D_suit_8-11.pdf?&cc=eng&lc=eng\|publisher=Keysight Technologies\|access-date=15 February 2017\|pages=21–33}}</ref> From MHL 3 onwards, the method for carrying the clock signal changed to being carried separately on the MHL CBUS pin instead.<ref name="mhl_keysight"/>
	=== superMHL 1.0 ===
	On January 6, 2015, MHL announced the superMHL 1.0 specification,<ref>{{citation \|title=superMHL Specification Version 1.0: Experience Beyond Resolution \|publisher=MHL Consortium \|url=http://www.mhlconsortium.org/whitepaper_request.aspx}}</ref><ref>{{Cite web\|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=5581\|title=MHL Consortium Announces SuperMHL – The First Audio/Video Specification With Support Up To 8k\|last=\|first=\|date=6 January 2016\|website=mhltech.org\|publisher=MHL, LLC\|access-date=}}</ref><ref>{{Cite web\|url=http://www.slideshare.net/mhltech/mhl-at-ces-2016\|title=MHL at CES 2016\|last=\|first=\|date=6 January 2016\|website=slideshare.net\|publisher=MHL Consortium\|access-date=}}</ref> the next-generation of MHL technology for CE and mobile devices. Features of superMHL include:

			The normal (24 bit) mode operates at 2.25 Gbit/s, and multiplexes the same three channel, 24 bit color signal as HDMI, at a pixel clock rate of up to 75 MHz, sufficient for ] and ] at 60 Hz. One period of the MHL clock equals one period of the pixel clock, and each period of the MHL clock transmits three 10-bit TMDS characters (i.e., a 24-bit pixel, where each 10-bit TMDS character represents an encoded byte – 8-bits).<ref name="mhl-synopsys"/><ref name="technical-overview_rohdeschwarz">{{cite web\|title=MHL (Mobile High-Definition Link) Technical overview\|url=https://cdn.rohde-schwarz.com/pws/dl_downloads/dl_common_library/dl_brochures_and_datasheets/pdf_1/MHL_po_en_folded_3606-6792-82_v0400.pdf\|publisher=Rohde & Schwarz\|access-date=15 February 2017}}</ref>
	* Delivery of up to ] 120fps video
	* Deep Color support up to 48-bit color depths
	* Wider color gamut to view content the way filmmakers intended
	* High-Dynamic Range (HDR) support to strike the perfect balance of bright spectral highlights along with shadow details
	* Immersive surround sound with support for object audio such as Dolby Atmos, DTS:X, 3D audio, and an audio-only mode
	* Advanced connectivity configurations to link multiple MHL devices together (TV, AVR, Blu-ray player) and control them via one remote
	* Power charging up to 40W
	* Content on multiple displays when connecting a single device
	* Backward compatible with MHL 1, MHL 2 and MHL 3
	* New reversible superMHL connector
	* Support for the MHL Alt Mode for the ] specification
	* HDCP 2.2

			MHL can also operate in PackedPixel mode at 3 Gbit/s, catering for ], in this case only two channels are multiplexed, as the color signal is changed to a ] (YCbCr 4:2:2) pair of adjacent 16-bit pixels (i.e., where two adjacent pixels share chroma values and are represented with only 36-bits), and the pixel clock is doubled to 150 MHz. In this mode, one clock period of the MHL clock now equals two periods of the pixel clock, so each period of the MHL clock transmits twice the number of channels i.e., four 10-bit TMDS characters (a pair of 16-bit pixels).<ref name="mhl_keysight"/><ref name="mhl-synopsys"/><ref name="technical-overview_rohdeschwarz"/>
	The superMHL standard makes use of one to six A/V lanes with each lane operating at 6Gbit/s. Four connectors have been detailed with their various numbers of A/V lanes supported in the standard:

			Version 3 of MHL changed from being frame-based to a packet-based technology,<ref name="mhl-hdmi-synopsys">{{cite web\|author1=Manmeet Walia\|title=HDMI and MHL IP for Mobile and Digital Home Connectivity\|url=https://www.synopsys.com/designware-ip/technical-bulletin/hdmi-and-mhl.html\|website=Synopsys.com\|access-date=14 April 2017}}</ref> and operates at 6 Gbit/s. superMHL extends this by carrying the data signal over more than one differential pair (up to four with USB Type-C, or a total of six using a superMHL cable) allowing up to 36 Gbit/s.
	* micro-USB (one A/V lane)
	* HDMI Type-A (one A/V lane)
	* USB Type-C (one to four A/V lanes)
	* superMHL (one to six A/V lanes)

			== Versions ==
	superMHL may also use a variety of source and sink connectors:
			All MHL specifications are backward compatible to previous versions of the standard. MHL is connection agnostic (i.e., not tied to a specific type of hardware connector). The first implementations used the 5-pin MHL-USB connector described below, and all are supported over USB Type-C MHL Alternate Mode. Other proprietary and custom connections are also allowed.

			=== MHL 1 ===
	* micro-USB (Source)
			Version 1.0 was introduced in June 2010, supporting uncompressed HD video up to 720p/1080i 60 Hz (with RGB and YCbCr 4:2:2/4:4:4 pixel encoding). Support for ] 60 Hz (YCbCr 4:2:2) was introduced in version 1.3.<ref name="MHL3Whitepaper"/> The specification supports standard SD (]) and HD (]) color spaces, as well as those introduced in HDMI 1.3 and 1.4 (], sYCC601, ], and AdobeYCC601).<ref name="MHL_Masud_Syed">{{cite web\|author=Masud Syed\|title=MHL: A multimedia connectivity standard\|url=http://www.electronicproducts.com/Digital_ICs/Communications_Interface/MHL_A_multimedia_connectivity_standard.aspx\|website=Electronic Products\|date=17 November 2014\|access-date=17 March 2017}}</ref> Other features include 192 kHz 24-bit ] 8-channel ] audio, ] 1.4 content protection, and a minimum of 2.5 W (500 mA) power between sink (e.g., TV) and source (e.g., mobile phone) for charging. The MHL sideband channel (MSC) includes a built-in Remote Control Protocol (RCP) function allowing the ] of the TV to operate the MHL mobile device through TV's ] (CEC) function, or allowing a mobile device to manage the playback of its content on the TV.<ref name="MHL_Masud_Syed"/>
	* USB Type-C (Source or Sink)<ref name="altmode_usb.org">{{Cite web\|url=https://web.archive.org/web/20160914061910/http://www.usb.org/developers/presentations/USB_DevDays_Taipei_2015_-_MHL_Alt_Mode_on_USB_Type-C.pdf\|title=MHL Alt Mode: Optimizing Consumer Video Transmission\|last=\|first=\|date=18 November 2015\|website=usb.org\|publisher=MHL, LLC\|access-date=}}</ref>
	* Proprietary connectors (Source)
	* HDMI Type-A (Sink)
	* superMHL connector (Source or Sink)

			=== MHL 2 ===
	superMHL supports delivery of video up to ] 120fps using 6 lanes (e.g. superMHL connector), 8K 60fps using 4 lanes (e.g. USB Type-C / superMHL connector) and 4K 60fps using 1 lane (e.g. micro-USB / HDMI Type-A / USB Type-C / superMHL connector).<ref name="altmode_usb.org" /> The superMHL standard makes use of VESA's Display Stream Compression (DSC) standard version 1.1 to allow for 2.0x, 2.5x, or 3.0x compression. This allows a superMHL source-to-sink connection to transfer 108Gbit/s of visually lossless (mathematically lossy) data.
			Version 2.0 was introduced in April 2012, and raised the minimum charging supply to 4.5 W (900 mA), with an optional 7.5 W (1.5 A) maximum allowed. Support for 3D video was also introduced, permitting 720p/1080i 60 Hz, and 1080p 24 Hz 3D video modes. The specification also included additional MHL sideband channel (MSC) commands.<ref>{{cite web\|title=MHL 2.0 Compliance Testing\|url=https://cdn.rohde-schwarz.com/pws/dl_downloads/dl_application/application_notes/7mb83/7BM83_0E.pdf\|publisher=Rohde & Schwarz\|access-date=2017-03-21\|archive-url=https://web.archive.org/web/20160304120645/http://cdn.rohde-schwarz.com/pws/dl_downloads/dl_application/application_notes/7mb83/7BM83_0E.pdf\|archive-date=2016-03-04\|url-status=dead}}</ref>

			=== MHL 3 ===
	The following resolutions and frame rates are supported by the superMHL standard (other resolutions and frame rates may be supported):
			Version 3.0 was introduced in August 2013, and added support for ] (3840 × 2160) 30 Hz video, increasing the maximum bandwidth from 3 Gbit/s to 6 Gbit/s. An additional YCbCr 4:2:0 pixel encoding for 4K resolution was also introduced, while the maximum charging supply was increased to 10 W (2 A).<ref name="MHL_Masud_Syed"/> Support for compressed lossless audio formats was added with support for ] and ].

			The specification increased the speed of the bi-directional data channel from 1 Mbit/s to 75 Mbit/s to enable concurrent 4K video and ] (HID) support, such as mice, keyboards, touchscreens, and game controllers.<ref>{{cite press release\|title=MHL Consortium Announces New Specification with Major Advancements for Mobile and Consumer Electronics Connectivity\|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=2147493678\|publisher=MHL, LLC\|access-date=21 March 2017\|date=20 August 2013}}</ref> Other features include support for simultaneous multiple displays, improved Remote Control Protocol (RCP) with new commands, and HDCP 2.2 content protection.
	* 720×480p@59.94/60 Hz
	* 720×576@50 Hz
	* 1280×720p@50/59.94/60 Hz
	* 1920×1080i@50/59.94/60 Hz
	* 1920×1080p@50/59.94/60 Hz
	* 3840×2160@24/25/30/48/50/60 Hz (4K UHD)
	* 5120×2880@24/25/50/60 Hz (5K UHD)
	* 7680×4320@24/25/30/50/60/120 Hz (8K UHD)

			=== superMHL ===
	The following pixel encodings and color spaces are supported by the superMHL standard:
			superMHL 1.0 was introduced in January 2015, supporting ] Ultra HD (7680 × 4320) 120 Hz ] video with wide color gamut (]) and 48-bit deep color.<ref name="superMHL_Whitepaper"/><ref>{{Cite web\|url=http://www.mhltech.org/PressReleaseDetail.aspx?id=5581\|title=MHL Consortium Announces SuperMHL – The First Audio/Video Specification With Support Up To 8k\|date=6 January 2016\|website=mhltech.org\|publisher=MHL, LLC}}</ref><ref>{{Cite web\|url=http://www.slideshare.net/mhltech/mhl-at-ces-2016\|title=MHL at CES 2016\|date=6 January 2016\|website=slideshare.net\|publisher=MHL Consortium}}</ref> Support for object-based audio formats were added, such as ] and ], with an audio-only mode also available. The Remote Control Protocol (RCP) was also extended to link multiple MHL devices together (e.g., TV, AVR, Blu-ray Disc player) and control them via one remote.

			The specification introduces a reversible 32-pin superMHL connector, which (along with USB Type-C) supports a higher charging power of up to 40 W (20 V / 2 A), and is designed for future bandwidth expansion. The increase in bandwidth over previous MHL versions is achieved by using multiple A/V lanes, each operating at 6 Gbit/s, with a maximum of six A/V lanes supported depending on device and connector type.<ref name="superMHL_Whitepaper"/> For example, Micro-USB and HDMI Type-A support one A/V lane, USB Type-C supports up to four A/V lanes, and the superMHL connector supports up to six A/V lanes (36 Gbit/s).
	* RGB 4:4:4 pixel encoding
	* YCbCr 4:4:4 pixel encoding
	* YCbCr 4:2:2 pixel encoding
	* YCbCr 4:2:0 pixel encoding (4K resolution and above)
	* xvYCC
	* BT.2020 (8K and 4K UHD)
	* Rec.709
	* sYCC601
	* AdobeYCC601
	* AdobeRGB
	The superMHL connector is considered to be more futuristic than the ] or ] connectors.{{By whom\|date=February 2017}} superMHL connector supports more A/V lanes, it has more pins and it is reversible (like ]). superMHL connector supports future bandwidth expansion and it can deliver more power than other connectors. While USB Type-C is considered to be a small form factor connector, the superMHL connector has a form factor comparable to HDMI Type-A connector.

			In addition to supporting a variable number of lanes, the specification supports ] ] (DSC) 1.1, a "visually lossless" (but mathematically lossy) video compression standard. In cases when the bandwidth of the available lane(s) is unable to meet the rate of the uncompressed video stream, bandwidth savings of up to 3:1 can be achieved with a DSC compression rate of 3.0×.<ref name="superMHL_Whitepaper"/> For example, 4K 60 Hz is possible using a single lane (e.g., Micro-USB / HDMI Type-A) with a DSC rate of 3.0×.<ref name="superMHL_Whitepaper"/>
	== MHL Alternate Mode for USB Type-C ==
	The MHL ] for ] connector standard was released on November 17, 2014.<ref>{{cite web\|url=http://www.mhltech.org/news/PressReleaseDetail.aspx?id=2147501807\|title=MHL RELEASES ALTERNATE MODE FOR NEW USB TYPE-C CONNECTOR\|publisher=mhltech.org\|accessdate=2014-11-20}}</ref> This supports MHL 1, 2, 3 and superMHL specifications for delivery of audio, video, data, and power over USB Type-C port. The Alt Mode allows connecting MHL enabled source devices to MHL display devices through the USB Type-C port. USB Type-C port can be used on MHL source/display devices. All MHL/superMHL features are supported on MHL Alt Mode. MHL Alt Mode enables devices to support simultaneous MHL audio/video plus USB 2.0 and/or USB 3.1 Gen 1 or Gen 2 data and power charging over the USB Type-C connector.

			superMHL can use a variety of source and sink connectors with certain limitations: micro-USB or proprietary connectors can be used for the source only, HDMI Type-A for the sink only, while the USB Type-C<ref name="altmode_usb.org">{{Cite web\|url=http://www.usb.org/developers/presentations/USB_DevDays_Taipei_2015_-_MHL_Alt_Mode_on_USB_Type-C.pdf\|title=MHL Alt Mode: Optimizing Consumer Video Transmission\|date=18 November 2015\|website=usb.org\|publisher=MHL, LLC\|url-status=bot: unknown\|archive-url=https://web.archive.org/web/20160914061910/http://www.usb.org/developers/presentations/USB_DevDays_Taipei_2015_-_MHL_Alt_Mode_on_USB_Type-C.pdf\|archive-date=14 September 2016}}</ref> and the superMHL connectors can be used for the source or sink.<ref name="superMHL_Whitepaper"/>
	Depending on the bandwidth requirement MHL Alt Mode can use variable number of ] channels/lanes, The Alt Mode allows delivery of video up to ] 60fps using only 1 lane, 4K 120fps using 2 lanes or ] 60fps using 4 lanes. MHL Alt Mode sends 1 to 4 TMDS channels over super-speed data pins and the (e)CBUS signal on 1 side-band pin of the USB Type-C connector. Compared to other USB Type-C Alt Modes, this takes fewer pins on the connector and delivers higher video resolutions and frame rates. Other than the usual functionality, bi-directional CBUS control-channel will be also used as the pixel clock for resolutions above 1080p 60fps. At a max pixel clock of 600 MHz, each of the TMDS channel will run at 6Gbit/s. When less than 4 TMDS channels are used, ] will be supported, otherwise ] has to be used for data transfer. The USB Power Delivery (]) standard enables the devices to draw up to 100W power over USB Type-C port.
	]

			== Connectors ==
	In common MHL Alt Mode implementations on mobile/tablet/laptops, the video from the ] will be converted to MHL signal by using a MHL transmitter chip. Popular transmitter chips accepts video in ] (]/]) or ] format and covert it to MHL format. The USB Type-C port controller functions as a switch/mux which passes through native MHL signal to the external devices. The dock/display devices may use a MHL bridge chip to covert the MHL signal to HDMI signal format and pass it to the display sink. Some display devices has the capability to directly process the MHL signal on the display sink.
			=== Micro-USB–to–HDMI (five-pin) ===
			The first implementations used the most common connection for non-Apple mobile phones at the time, (]), and the most common TV connection (]). There are two types of connection, depending on whether the display device directly supports MHL.

			==== Passive cable ====
	== Comparison with SlimPort / Mobility DisplayPort (MyDP) ==
			Passive cables allow MHL devices to connect directly to MHL-enabled TVs (i.e. display devices or AV receivers with an MHL-enabled HDMI port) while providing charging power upstream to the mobile device. Other than the physical connectors, no USB or HDMI technology is being used. Exclusively MHL signaling is used through the connectors and over the cable.
	] is a proprietary alternative to MHL, based on the ] standard integrated into common microUSB ports and supports up to 1080p60 or 1080p30 with 3D content over HDMI 1.4 (up to 5.4 Gbit/s of bandwidth), in addition to support for DVI, VGA (up to 1920 x 1080 at 60 Hz), and DisplayPort.<ref>http://www.slimportconnect.com/support/</ref> Implementers of SlimPort may be subject to the MPEG-LA patent pool license for DisplayPort. On March 5, 2015, the MPEG LA announced their DisplayPort license, which is US$0.20 per DisplayPort product.

	== ~~Connectors~~ ==		==== Active adapter ====
			With an active adapter, MHL devices are able to connect to HDMI display devices that do not have MHL capability by actively converting the signal to HDMI. These adapters often feature an additional Micro-USB port on them to provide charging power to the mobile device because standard HDMI ports do not supply sufficient current.
	]

	=== ~~Standard~~ Micro-~~USB-to-HDMI~~ adapter (~~five~~-pin) ===		=== Samsung Micro-USB–to–HDMI adapter and tip (eleven-pin) ===
			The ], and later ] and ], use an 11-pin connector and the six additional connector pins in order to achieve functional improvements over the 5-pin design (like simultaneous USB-OTG use<ref name="Galaxy S3 MHL explanation">{{cite web\|title=Galaxy S3 MHL explanation \|url=http://www.galaxymhl.com/ \|url-status=dead \|archive-url=https://web.archive.org/web/20150516154008/http://www.galaxymhl.com/ \|archive-date=16 May 2015 }}</ref>). However, if consumers have a standard MHL-to-HDMI adapter all they need to purchase is a tip. With the launch of the Samsung Galaxy S4, Samsung also released MHL 2.0 smart adapter with a built-in 11-pin connector. The first Samsung MHL 1.0 smart adapter released with the Galaxy S III requires external power and is able to work with HDMI TVs at 1080p at 24 Hz.<ref name="MHL 2.0 HDTV Smart Adapter">{{cite web\|title=MHL 2.0 HDTV Smart Adapter\|url=http://www.samsung.com/us/mobile/cell-phones-accessories/ET-H10FAUWESTA}}</ref> The MHL 2.0 adapter released with the Galaxy S4 can output 1080p at 60 Hz and does not need external power.
	The first implementations use the most popular mobile connection (]) and the most popular TV connection (]). Other than the physical connectors, no USB or HDMI technology is being used. Exclusively MHL signaling is used through the connectors and over the cable.

	=== ~~Samsung~~ ~~Micro~~-~~USB-to-HDMI~~ ~~adapter~~ ~~and~~ ~~tip (eleven-pin~~) ===		=== USB Type-C (MHL Alternate Mode) ===
			{{Main article\|USB-C}}
	The ], and later ] and ], use an 11-pin connector and the six additional connector pins in order to achieve functional improvements over the 5-pin design (like simultaneous USB-OTG use<ref name="Galaxy S3 MHL explanation">{{cite web\|title=Galaxy S3 MHL explanation\|url=http://www.galaxymhl.com/}}</ref>). However, if consumers have a standard MHL-to-HDMI adapter all they need to purchase is a tip. With the launch of the Samsung Galaxy S4, Samsung also released a Samsung 2.0 smart adapter with a built-in 11-pin connector. The first generation Samsung MHL 2.0 smart adapter released with the Galaxy S III requires external power and is able to work with HDMI TVs at 1080p at 24 Hz.<ref name="MHL 2.0 HDTV Smart Adapter">{{cite web\|title=MHL 2.0 HDTV Smart Adapter\|url=http://www.samsung.com/us/mobile/cell-phones-accessories/ET-H10FAUWESTA}}</ref> The second generation adapter released with the Galaxy S4 can output 1080p at 60 Hz and does not need external power.

			The MHL ] for ] specification allows MHL enabled source and display devices to be connected through a USB Type-C port. The standard was released on November 17, 2014, and is backward compatible with existing MHL specifications: supporting MHL 1, 2, 3 and superMHL.<ref>{{cite press release\|url=http://www.mhltech.org/news/PressReleaseDetail.aspx?id=2147501807\|title=MHL Releases Alternate Mode for New USB Type-C Connector\|website=mhltech.org\|access-date=2014-11-20 \|date=November 17, 2014}}</ref> The standard supports the simultaneous transfer of data (at least ], and depending on video resolution: ] Gen 1 or 2) and power charging (up to 40 W via ]), in addition to MHL audio/video.<ref name="superMHL_Whitepaper"/> This allows the connection to be used with mobile ], allowing devices to connect to other peripherals while charging. The use of passive cables is possible when both devices support the standard, e.g., when connecting to superMHL, USB Type-C, and MHL-enabled HDMI, otherwise, an active cable adapter is necessary to connect to standard HDMI devices.<ref name="altmode_usb.org" />
	=== MHL passive cable ===
	Passive cables allow consumers to connect an MHL-enabled device directly to an MHL TV and do not require external power. Unlike older MHL adapters and cables, the passive cable simultaneously charges the cell phone battery while mirroring.

			Depending on the bandwidth requirement, the standard makes use of a variable number of USB Type-C's four SuperSpeed differential pairs to carry each ] lane: a single lane is required for resolutions up to ]/60 Hz, two lanes for 4K/120 Hz, and all four lanes for ]/60 Hz.<ref name="altmode_usb.org"/> The MHL eCBUS signal is sent over a side-band (SBU) pin on the USB Type-C connector. When one or two lanes are used, USB 3.1 data transfer is supported.
	=== USB Type-C ===
			]
	{{Main article\|USB Type-C}}

			In common MHL Alternate Mode implementations, the video from the ] will be converted to an MHL signal by using an MHL transmitter chip. The transmitter chips often accept video in ] (]/]) or ] format and convert it to MHL format. The USB Type-C port controller functions as a switch and multiplexer, passing the MHL signal through to the external devices. The dock or display device may use an MHL bridge chip to convert the MHL signal to HDMI signal format.
	Using ], USB Type-C ports are used on MHL source or display devices. USB Type-C is a totally reversible connector. The USB Type-C connector is used on active devices like mobile/laptop docks, which converts it to other video formats (e.g. ], ], ], ]). The USB Type-C connector is also used on passive cables with an HDMI/USB Type-C/superMHL connector on the other end.

	=== superMHL (32-pin) ===		=== superMHL (32-pin) ===
	On ~~January~~ 6, 2015, MHL introduced ~~the new~~ reversible superMHL connector. ~~This 32 pin~~ connector can carry ~~concurrent~~ ~~video,~~ ~~data~~ ~~and~~ ~~power~~ ~~charging~~ ~~all~~ in a ~~slim,~~ ~~consumer-friendly~~ ~~form~~ ~~factor.~~ A ~~reversible~~ ~~design~~ ~~means~~ ~~that~~ ~~consumers~~ ~~don't~~ ~~have~~ to ~~worry~~ ~~about~~ ~~the~~ ~~plug's~~ ~~orientation~~ or ~~the~~ ~~cable's~~ ~~direction~~.		In conjunction with the release of the superMHL specification in January 2015, MHL introduced a reversible 32-pin superMHL connector. The connector can carry six A/V lanes over six differential pairs, catering for the full 36 Gbit/s bandwidth available from the superMHL standard. The connector also enables 40 W of charging power at a higher voltage and current.<ref name="superMHL_Whitepaper"/>

			== Alternatives ==
	== Announcements and products ==
			] is a proprietary alternative to MHL, based on the ] standard integrated into common Micro-USB ports, and supports up to 1080p60 or 1080p30 with 3D content over HDMI 1.4 (up to 5.4 Gbit/s of bandwidth), in addition to support for DVI, VGA (up to 1920 × 1080 at 60 Hz), and DisplayPort.<ref>{{cite web\|title=Support\|url=http://world.slimportconnect.com/support/\|website=Slimport \|access-date=2017-04-27}}</ref>
	* '''MHL''' announced on January 6, 2015 the superMHL, the first audio/video specification with support up to 8K and a new consumer-friendly, reversible superMHL connector for CE devices
	* '''MHL''' announced on November 17, 2014 MHL Alternate Mode ("Alt Mode") for the USB Type-C specification
	* '''MHL''' announced on August 20, 2013 the MHL 3.0 specification with major advancements for mobile and CE connectivity
	* '''MHL''' announced on August 26, 2013 its MHL Experience Program with SEGA, PowerA, Nyko, MobiSystems, Green Throttle and FilmOn.TV
	* '''MHL''' announced on May 28, 2013 that it had reached 200 adopter milestone
	* '''Samsung''' March 14, 2013, Samsung release Galaxy S4 with MHL 2.0
	* '''HTC''' February 19, 2013, HTC release the New HTC One with MHL
	* '''MHL''' announced on January 7, 2013 that there was an installed base of more than 220 million products and greater than 200 products in the marketplace.
	* '''Hyundai''' announced on January 4, 2013 that it would be showing working versions of future vehicle infotainment systems, including MHL technology.
	* '''Silicon Image''' expanded its MHL product line with four new products that included the latest MHL 2.0 features on September 25, 2012.<ref>{{cite news \|title=Silicon Image Unveils First MHL Products\|publisher=Silicon Image \|url=http://www.siliconimage.com/news/releasedetails.aspx?id=617 \|date=October 4, 2010 \|accessdate=2011-02-15}}</ref>
	* '''LG Electronics''' available on December 4, 2011 ] and ] ] (AT&T) / ] (] carriers), a ] AH-] display on the device with MHL output abilities for any TV equipped with ] input.<ref>{{cite press release \| title=LG Nitro HD Delivers First True High-Definition Experience for AT&T Customers\|publisher=AT&T Wireless \|url=http://www.att.com/gen/press-room?pid=22079&cdvn=news&newsarticleid=33416 \|date=November 28, 2011 \|accessdate=2011-11-28}}</ref><ref>{{cite press release \| title=WORLD’S FIRST HD LTE SMARTPHONE ANNOUNCED IN CANADA \|publisher=LG Electronics \|url=http://www.lgnewsroom.com/newsroom/contents/61609 \|date=November 8, 2011 \|accessdate=2011-11-08}}</ref><ref>{{cite press release \| title=LG LAUNCHES OPTIMUS LTE, FIRST 4G HD SMARTPHONE IN KOREAN MARKET \|publisher=LG Electronics \|url=http://www.lgnewsroom.com/newsroom/contents/61566 \|date=October 4, 2011 \|accessdate=2011-10-04}}</ref>
	* '''HTC''' announced at the 2011 CTIA that their "EVO 3D" mobile device supports MHL output and in addition that the HTC "Sensation" will also have this capability, as well as its successor, the "Sensation XE". The HTC Rezound, which is a sister device to the Sensation XE also has the MHL port.
	* '''Samsung''' announced at the 2011 ] that their ] mobile devices feature MHL connections.<ref name="MWC2011_interview" /><ref>{{cite news \|title=The Samsung Galaxy S2 is Announced \|publisher=MobileReview \|url=http://forum2.mobile-review.com/showthread.php?p=920977 \|date=February 15, 2011 \|accessdate=2011-02-15}}</ref><ref>{{cite web\| url=https://www.ruconnected.nl/hdmi-2-1/\| title= HDMI 2.1 }} Wednesday, 1 February 2017 </ref>
	* '''Onkyo''' and '''Silicon Image''' announced on December 21, 2011 the world's first A/V receivers featuring InstaPrevue and MHL technologies.<ref>{{cite press release \| title=Onkyo and Silicon Image Announce the World’s First A/V Receivers Featuring InstaPrevue and MHL Technologies. \|publisher=Onkyo US\|url=http://www.onkyousa.com/Info/pressreleases.php\|date=December 21, 2011 \|accessdate=2012-06-06}}</ref>

	== See also ==		== See also ==
	* ] (wireless display technology)
	* SlimPort (]), also known as MyDP		* SlimPort (]), also known as MyDP
			* ] (wireless display technology)
			* ] (proprietary media broadcast over IP: ] for audio or audiovisual playback)
			* ] (proprietary IP-based)
			* ] (DLNA) (IP-based)
			* ] version 3.5 to 6.0 supports ]; discontinued
			* ]
			* ] proprietary
			* ]

	== References==		==References==
	{{reflist\|30em}}		{{reflist\|30em}}

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	{{commons category}}		{{commons category}}
	* {{official website\|www.mhltech.org}}		* {{official website\|www.mhltech.org}}
	*

	{{AVconn}}		{{AVconn}}
	{{High-definition}}		{{High-definition}}

	]		]
			]
	]		]
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Revision as of 22:19, 25 April 2024

Industry standard

Mobile High-Definition Link (MHL)
Production history

Type	Digital audio/video/data connector
Designer	MHL Consortium Nokia Samsung Silicon Image Sony Toshiba
Designed	June 2010; 14 years ago (June 2010)
General specifications
Hot pluggable	Yes
External	Yes
Pins	MHL 1, 2, & 3 (5), superMHL (5/24/32)

Mobile High-Definition Link (MHL) is an industry standard for a mobile audio/video interface that allows the connection of smartphones, tablets, and other portable consumer electronics devices to high-definition televisions (HDTVs), audio receivers, and projectors. The standard was designed to share existing mobile device connectors, such as Micro-USB, and avoid the need to add video connectors on devices with limited space for them.

MHL connects to display devices either directly through special HDMI inputs that are MHL-enabled, or indirectly through standard HDMI inputs using MHL-to-HDMI adapters. MHL was developed by a consortium of five companies: Nokia, Samsung, Silicon Image, Sony and Toshiba.

History

Silicon Image, one of the founding companies of the HDMI standard, originally demonstrated a mobile interconnect at the January 2008 Consumer Electronics Show (CES), based on its transition-minimized differential signaling (TMDS) technology. This interface was termed "Mobile High Definition Link" at the time of the demonstration, and is a direct precursor of the implementation announced by the MHL Consortium. The company is quoted as saying it did not ship that original technology in any volume, but used it as a way to get a working group started.

The working group was announced in September 2009, and the MHL Consortium founded in April 2010 by Nokia, Samsung, Silicon Image, Sony and Toshiba. The MHL specification version 1.0 was released in June 2010, and the Compliance Test Specification (CTS) was released in December 2010. May 2011 marked the first retail availability of MHL-enabled products.

The first mobile device to feature the MHL standard was the Samsung Galaxy S II, announced at the 2011 Mobile World Congress. MHL announced in 2014 that more than half a billion MHL-capable products had been shipped since the standard was created.

Overview

MHL is an adaptation of HDMI intended for mobile devices such as smartphones and tablets. Unlike DVI, which is compatible with HDMI using only passive cables and adapters, MHL requires that the HDMI socket be MHL-enabled. (To deliver an MHL signal to a non-MHL HDMI socket, one can use an adapter device that receives the signal on an MHL-enabled socket, converts it to HDMI, and transmits the HDMI signal to the non-MHL socket). It has several aspects in common with HDMI, such as the ability to carry uncompressed HDCP encrypted high-definition video, eight-channel surround sound, and control remote devices with Consumer Electronics Control (CEC).

There are a total of five pins used in MHL rather than the 19 used in HDMI, namely: a differential pair for data, a bi-directional control channel (CBUS), power charging supply, and ground. This permits a much lighter cable and a much smaller connector on the mobile device, as a typical MHL source will be shared with USB 2.0 on a standard 5-pin Micro-USB receptacle. (Although MHL ports can be dedicated to MHL alone, the standard is designed to permit port sharing with the most commonly used ports.) The USB port switches from USB to MHL when it recognizes an MHL-qualified sink (e.g., a TV) detected on the control wire. A typical MHL sink will be shared with HDMI on a standard 19-pin HDMI receptacle.

Because the same five-pin Micro-USB port is also typically used for charging the device, the sink is required to provide power to maintain the state of charge (or even recharge) while it is being used (although this is dependent on the power available being sufficient e.g., MHL 2 & 3 provide a minimum of 4.5 W / 900 mA, while superMHL can provide up to 40 W). The use of the power line in this way differs from HDMI, which expects the source to provide 55 mA for the purpose of reading the EDID of a display.

Because of to the low pin count of MHL versus HDMI, the functions that are carried on separate dedicated pins on HDMI, namely: the Display Data Channel (DDC) (pins 15 & 16) and CEC (pin 13) are instead carried on the bi-directional control bus (CBUS). The CBUS both emulates the function of the DDC bus and also carries an MHL sideband channel (MSC), which emulates the CEC bus function, and allows a TV remote to control the media player on a phone with its Remote Control Protocol (RCP).

Bandwidth

MHL uses the same Transition-minimized differential signaling (TMDS) as HDMI to carry video, audio, and auxiliary data. However, MHL differs from HDMI in that there is only one differential pair to carry the TMDS data lane, compared to HDMI's four (three data lanes, plus the clock). Therefore these three logical data channels are instead time-division multiplexed into the single physical MHL data lane (i.e., with the logical channels sent sequentially), and the clock signal carried as a common mode signal of this pair. From MHL 3 onwards, the method for carrying the clock signal changed to being carried separately on the MHL CBUS pin instead.

The normal (24 bit) mode operates at 2.25 Gbit/s, and multiplexes the same three channel, 24 bit color signal as HDMI, at a pixel clock rate of up to 75 MHz, sufficient for 1080i and 720p at 60 Hz. One period of the MHL clock equals one period of the pixel clock, and each period of the MHL clock transmits three 10-bit TMDS characters (i.e., a 24-bit pixel, where each 10-bit TMDS character represents an encoded byte – 8-bits).

MHL can also operate in PackedPixel mode at 3 Gbit/s, catering for 1080p, in this case only two channels are multiplexed, as the color signal is changed to a chroma subsampled (YCbCr 4:2:2) pair of adjacent 16-bit pixels (i.e., where two adjacent pixels share chroma values and are represented with only 36-bits), and the pixel clock is doubled to 150 MHz. In this mode, one clock period of the MHL clock now equals two periods of the pixel clock, so each period of the MHL clock transmits twice the number of channels i.e., four 10-bit TMDS characters (a pair of 16-bit pixels).

Version 3 of MHL changed from being frame-based to a packet-based technology, and operates at 6 Gbit/s. superMHL extends this by carrying the data signal over more than one differential pair (up to four with USB Type-C, or a total of six using a superMHL cable) allowing up to 36 Gbit/s.

Versions

All MHL specifications are backward compatible to previous versions of the standard. MHL is connection agnostic (i.e., not tied to a specific type of hardware connector). The first implementations used the 5-pin MHL-USB connector described below, and all are supported over USB Type-C MHL Alternate Mode. Other proprietary and custom connections are also allowed.

MHL 1

Version 1.0 was introduced in June 2010, supporting uncompressed HD video up to 720p/1080i 60 Hz (with RGB and YCbCr 4:2:2/4:4:4 pixel encoding). Support for 1080p 60 Hz (YCbCr 4:2:2) was introduced in version 1.3. The specification supports standard SD (Rec. 601) and HD (Rec. 709) color spaces, as well as those introduced in HDMI 1.3 and 1.4 (xvYCC, sYCC601, Adobe RGB, and AdobeYCC601). Other features include 192 kHz 24-bit LPCM 8-channel surround sound audio, HDCP 1.4 content protection, and a minimum of 2.5 W (500 mA) power between sink (e.g., TV) and source (e.g., mobile phone) for charging. The MHL sideband channel (MSC) includes a built-in Remote Control Protocol (RCP) function allowing the remote control of the TV to operate the MHL mobile device through TV's Consumer Electronics Control (CEC) function, or allowing a mobile device to manage the playback of its content on the TV.

MHL 2

Version 2.0 was introduced in April 2012, and raised the minimum charging supply to 4.5 W (900 mA), with an optional 7.5 W (1.5 A) maximum allowed. Support for 3D video was also introduced, permitting 720p/1080i 60 Hz, and 1080p 24 Hz 3D video modes. The specification also included additional MHL sideband channel (MSC) commands.

MHL 3

Version 3.0 was introduced in August 2013, and added support for 4K Ultra HD (3840 × 2160) 30 Hz video, increasing the maximum bandwidth from 3 Gbit/s to 6 Gbit/s. An additional YCbCr 4:2:0 pixel encoding for 4K resolution was also introduced, while the maximum charging supply was increased to 10 W (2 A). Support for compressed lossless audio formats was added with support for Dolby TrueHD and DTS-HD Master Audio.

The specification increased the speed of the bi-directional data channel from 1 Mbit/s to 75 Mbit/s to enable concurrent 4K video and human interface device (HID) support, such as mice, keyboards, touchscreens, and game controllers. Other features include support for simultaneous multiple displays, improved Remote Control Protocol (RCP) with new commands, and HDCP 2.2 content protection.

superMHL

superMHL 1.0 was introduced in January 2015, supporting 8K Ultra HD (7680 × 4320) 120 Hz High Dynamic Range (HDR) video with wide color gamut (Rec. 2020) and 48-bit deep color. Support for object-based audio formats were added, such as Dolby Atmos and DTS:X, with an audio-only mode also available. The Remote Control Protocol (RCP) was also extended to link multiple MHL devices together (e.g., TV, AVR, Blu-ray Disc player) and control them via one remote.

The specification introduces a reversible 32-pin superMHL connector, which (along with USB Type-C) supports a higher charging power of up to 40 W (20 V / 2 A), and is designed for future bandwidth expansion. The increase in bandwidth over previous MHL versions is achieved by using multiple A/V lanes, each operating at 6 Gbit/s, with a maximum of six A/V lanes supported depending on device and connector type. For example, Micro-USB and HDMI Type-A support one A/V lane, USB Type-C supports up to four A/V lanes, and the superMHL connector supports up to six A/V lanes (36 Gbit/s).

In addition to supporting a variable number of lanes, the specification supports VESA Display Stream Compression (DSC) 1.1, a "visually lossless" (but mathematically lossy) video compression standard. In cases when the bandwidth of the available lane(s) is unable to meet the rate of the uncompressed video stream, bandwidth savings of up to 3:1 can be achieved with a DSC compression rate of 3.0×. For example, 4K 60 Hz is possible using a single lane (e.g., Micro-USB / HDMI Type-A) with a DSC rate of 3.0×.

superMHL can use a variety of source and sink connectors with certain limitations: micro-USB or proprietary connectors can be used for the source only, HDMI Type-A for the sink only, while the USB Type-C and the superMHL connectors can be used for the source or sink.

Connectors

Micro-USB–to–HDMI (five-pin)

The first implementations used the most common connection for non-Apple mobile phones at the time, (Micro-USB), and the most common TV connection (HDMI). There are two types of connection, depending on whether the display device directly supports MHL.

Passive cable

Passive cables allow MHL devices to connect directly to MHL-enabled TVs (i.e. display devices or AV receivers with an MHL-enabled HDMI port) while providing charging power upstream to the mobile device. Other than the physical connectors, no USB or HDMI technology is being used. Exclusively MHL signaling is used through the connectors and over the cable.

Active adapter

With an active adapter, MHL devices are able to connect to HDMI display devices that do not have MHL capability by actively converting the signal to HDMI. These adapters often feature an additional Micro-USB port on them to provide charging power to the mobile device because standard HDMI ports do not supply sufficient current.

Samsung Micro-USB–to–HDMI adapter and tip (eleven-pin)

The Samsung Galaxy S III, and later Galaxy Note II and Galaxy S4, use an 11-pin connector and the six additional connector pins in order to achieve functional improvements over the 5-pin design (like simultaneous USB-OTG use). However, if consumers have a standard MHL-to-HDMI adapter all they need to purchase is a tip. With the launch of the Samsung Galaxy S4, Samsung also released MHL 2.0 smart adapter with a built-in 11-pin connector. The first Samsung MHL 1.0 smart adapter released with the Galaxy S III requires external power and is able to work with HDMI TVs at 1080p at 24 Hz. The MHL 2.0 adapter released with the Galaxy S4 can output 1080p at 60 Hz and does not need external power.

USB Type-C (MHL Alternate Mode)

Main article: USB-C

The MHL Alternate Mode for USB 3.1 specification allows MHL enabled source and display devices to be connected through a USB Type-C port. The standard was released on November 17, 2014, and is backward compatible with existing MHL specifications: supporting MHL 1, 2, 3 and superMHL. The standard supports the simultaneous transfer of data (at least USB 2.0, and depending on video resolution: USB 3.1 Gen 1 or 2) and power charging (up to 40 W via USB Power Delivery), in addition to MHL audio/video. This allows the connection to be used with mobile docks, allowing devices to connect to other peripherals while charging. The use of passive cables is possible when both devices support the standard, e.g., when connecting to superMHL, USB Type-C, and MHL-enabled HDMI, otherwise, an active cable adapter is necessary to connect to standard HDMI devices.

Depending on the bandwidth requirement, the standard makes use of a variable number of USB Type-C's four SuperSpeed differential pairs to carry each TMDS lane: a single lane is required for resolutions up to 4K/60 Hz, two lanes for 4K/120 Hz, and all four lanes for 8K/60 Hz. The MHL eCBUS signal is sent over a side-band (SBU) pin on the USB Type-C connector. When one or two lanes are used, USB 3.1 data transfer is supported.

In common MHL Alternate Mode implementations, the video from the GPU will be converted to an MHL signal by using an MHL transmitter chip. The transmitter chips often accept video in MIPI (DSI/DPI) or HDMI format and convert it to MHL format. The USB Type-C port controller functions as a switch and multiplexer, passing the MHL signal through to the external devices. The dock or display device may use an MHL bridge chip to convert the MHL signal to HDMI signal format.

superMHL (32-pin)

In conjunction with the release of the superMHL specification in January 2015, MHL introduced a reversible 32-pin superMHL connector. The connector can carry six A/V lanes over six differential pairs, catering for the full 36 Gbit/s bandwidth available from the superMHL standard. The connector also enables 40 W of charging power at a higher voltage and current.

Alternatives

SlimPort is a proprietary alternative to MHL, based on the DisplayPort standard integrated into common Micro-USB ports, and supports up to 1080p60 or 1080p30 with 3D content over HDMI 1.4 (up to 5.4 Gbit/s of bandwidth), in addition to support for DVI, VGA (up to 1920 × 1080 at 60 Hz), and DisplayPort.

References

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^ "superMHL Specification - White Paper" (PDF). MHL. September 2015. Archived from the original (PDF) on 8 February 2017. Retrieved 7 February 2017.
"Mobile High-Definition Link (MHL™) Technology". Silicon Image. Archived from the original on 10 January 2010.
"HDMI plugs into cameras, cellphones". EETimes.com. January 8, 2008. Retrieved 2010-04-14.
"Silicon Image angles to extend its HDMI success to handsets". EETimes.com. 14 July 2008. Retrieved 2010-04-14.
"Consortium backs mobile interface for high def video". EETimes.com. April 14, 2010. Retrieved 2010-04-14.
"Leading Companies Form Mobile High-Definition Interface Working Group to Drive Industry Standard for Mobile Wired Connectivity" (Press release). Silicon Image. September 28, 2009. Archived from the original on 2011-07-16. Retrieved 2009-09-30.
"MHL 1.0 Specification and Adopter Agreement Now Available" (Press release). MHL, LLC. June 30, 2010. Archived from the original on October 27, 2015. Retrieved 2010-06-30.
"MHL Consortium Releases Compliance Test Specification to Growing Adopter Base" (Press release). MHL, LLC. December 21, 2010. Retrieved 2010-12-22.
"MHL Technology Reaches Major Milestone with the First MHL-Enabled Smartphones Now in Mass Production" (Press release). MHL, LLC. May 16, 2011. Retrieved 2017-04-25.
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^ Manmeet Walia. "MHL: The New Mobile-to-TV Protocol". Synopsys.com. Retrieved 15 February 2017.
"HDMI Resources: Knowledge Base". hdmi.org. Archived from the original on 25 May 2015. Retrieved 14 April 2017.
^ "Enable New Generation of Display Interface: Introducing MHL 3.2" (PDF). Keysight Technologies. pp. 21–33. Retrieved 15 February 2017.
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Manmeet Walia. "HDMI and MHL IP for Mobile and Digital Home Connectivity". Synopsys.com. Retrieved 14 April 2017.
^ Masud Syed (17 November 2014). "MHL: A multimedia connectivity standard". Electronic Products. Retrieved 17 March 2017.
"MHL 2.0 Compliance Testing" (PDF). Rohde & Schwarz. Archived from the original (PDF) on 2016-03-04. Retrieved 2017-03-21.
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"MHL Consortium Announces SuperMHL – The First Audio/Video Specification With Support Up To 8k". mhltech.org. MHL, LLC. 6 January 2016.
"MHL at CES 2016". slideshare.net. MHL Consortium. 6 January 2016.
^ "MHL Alt Mode: Optimizing Consumer Video Transmission" (PDF). usb.org. MHL, LLC. 18 November 2015. Archived from the original on 14 September 2016.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
"Galaxy S3 MHL explanation". Archived from the original on 16 May 2015.
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"Support". Slimport. Retrieved 2017-04-27.

External links

Official website

v t e Audio and video connectors
Analog audio	Banana plug Binding post D-subminiature Euroblock DIN Mini-DIN Audio jack RCA Speaker spring terminal Speakon XLR
Digital audio	BNC D-sub S/PDIF TOSLINK XLR
Video	BNC Component RGB Component YPbPr Composite video D-Terminal DB13W3 DFP DIN Mini-DIN DMS-59 LFH DVI Mini-DVI Micro-DVI RCA S-Video UDI VGA Mini-VGA
Audio and video	ADC Belling-Lee CCJ/EIAJ EVC Type F HDBaseT HDMI DisplayPort mDP MHL (superMHL) Minijack P&D PDMI SCART
Visual charts	List of video connectors
General-purpose	Thunderbolt USB

v t e High-definition (HD)
Concepts	High-definition television High-definition video Ultra-high-definition television
Resolutions	720p (HD) 1080i (Full HD) 1080p (Full HD) 1440p (Quad HD) 2160p (4K Ultra HD) 4320p (8K Ultra HD) 8640p (16K Ultra HD)
Analog broadcast (All defunct)	819 line system HD MAC MUSE (Hi-Vision)
Digital broadcast	ATSC DMB-T/H DVB ISDB SBTVD
Audio	Dolby Digital Surround sound DSD DXD DTS
Filming and storage	DCI HDV
HD media and compression	Archival Disc AV1 Blu-ray CBHD D-VHS DVD-Audio H.264 H.265 H.266 HD DVD HD VMD MPEG-2 MUSE LaserDisc MVC Super Audio CD Ultra HD Blu-ray Uncompressed VC-1 W-VHS
Connectors	Component DisplayPort DVI HDMI VGA
Deployments	List of digital television deployments by country

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