T436 - Fall 2007 - Week 13

Agenda

• Cut list / project status
• Editing codecs
• Production meeting: shoots this week:
  • I got to get out of this place?
• Critical review in lecture time next week

Announcements/Reality check

THis week we'll look at some of the remaining stories and offer some suggestions. We'll be having a premiere the week after Thanksgiving either Monday or Wednesday. I'm inviting a few people such as Brent Molnar, Steve Krahnke, and Ron Osgood to come in and give some feedback.

Here's what still remains to be done:

• Turn in talent releases (You'll get an incomplete until you turn these in)
• Turn in writers license agreements (You'll get an incomplete until you turn these in)

Some of the stories aren't as clear or developed as they should. I've put a cut sheet together which lists what needs to be done on what. All need some work, The Director/Producers are responsible for making sure they get completed. Some need additional segments shot to make them stronger. Re-shoots need to be figured out today since they need to happen over Thanksgiving or the week after Thanksgiving.

Extra Credit: Shoot Host intro and segues into various shorts. Since the quaility of the shorts and whether we're using them has yet to be determined, this production will likely occur as an extra credit opportunity. I'll make a production team out of people who need to raise their grades. Like the other productions, this will be anywhere from 30-50 points depending upon your role.

HDTV Codecs

HDV uses a form of MPEG compression. MPEG-2 uses interframe compression, which compresses both spatially and temporally. Intraframe codecs such as DV treat each frame individually and thus only compress spatially. Because MPEG-2 can compress over time as well as space it is capable of delivering a high-quality image in a smaller amount of bandwidth than an intraframe codec can deliver. A great deal of MPEG-2’s efficiency is due to the fact it compresses the video into groups of pictures (GOPs) and not simply individual frames. In MPEG-2 compression, images are divided into macroblocks, which are typically areas of 16 x 16 pixels. The GOPs are created with three types of pictures: I, P, and B frames. I frames are intracoded frames, which are sometimes referred to as index frames. P are predicted frames and B are bidirectional frames. A GOP starts with an I frame. In MPEG-2 compression, P frames are compared to the previous I or P frame. If there is a difference, a proper vector is determined to move the macroblock. If there is no change (if there is no movement within the shot), the bit rate can be reduced significantly. B frames, or bidirectional frames work similarly, but reference previous and future frames.

Some compression methods use intraframe compression, which treats every frame individually, compressing one after the next. These types of compressors such as M-JPEG or DV, facilitate editing because each frame is independent of the others and can be accessed at any point in the stream. Since MPEG-2 breaks the video stream into chunks known as GOPs, ease of editing is reduced in favor of maximizing compression. So while MPEG-2 is perhaps ideal for transmission, its multi-frame GOP structure is not optimized for editing. It is possible to edit MPEG-2 without recompression as long as the edit points resides on a GOP boundary.

HD Production Formats

D-VHS – This consumer format from JVC records onto VHS tapes using an MPEG-2 stream at up to a 28.2 Mbps data rate. It’s backwards compatible with VHS appealing to consumers with sizable VHS tape collections. It is not considered a viable commercial production format.

HDV – Canon, Sony and JVC offer lower cost HDV cameras that record at a maximum resolution of 1440 x 1080. HDV uses a form of MPEG-2 compression that can be recorded onto miniDV cassettes. In 1080i mode, HDV can record a 25 Mbps signal. In 720p mode it records at 19 Mbps. Because MPEG-2 employs Groups of Pictures (GOPs) instead of discreet frames, HDV data is often up-converted into a different format for editing. Because the data rate is relatively low, HDV content can easily be transferred over a FireWire (IEEE-1394) connection.

DVCPRO HD – Also known as D12, DVCPRO HD was developed by Panasonic and has versions that record on magnetic tape as well as memory cards. The 100Mbps data rate is still low enough to be transferred over a FireWire connection from a VTR into an editing system. DVCPRO HD is restricted to a maximum resolution of 1280 x 1080 pixels.

XDCAM HD  - Sony’s tapeless format records onto Blu-Ray optical discs using several possible frame rates and codecs. It can record HD content using MPEG-2 encoding at 35 Mbps or DVCAM at 25 Mbps. Its HD resolution is restricted to 1440 x 1080 pixels.

D-5 HD – Developed by Panasonic in 1991, the D-5 format has been updated to HD. It records at a 235 Mbps data rate and can handle 720 and 1080 content at most possible frame rates.

HDCAM - Sony’s format records onto 1/2” videocassettes at a number of possible frame rates. It uses a 140 Mbps data rate and supports up to 4 channels of audio. It too is restricted to a maximum resolution of 1440 x 1080 pixels.

HDCAM SR – Sony’s higher end version of HDCAM shares some of the same features but can write data rates up to 880 Mbps with up to 12 audio channels.

Name	Format	Pixel dimensions (recorded)	Color sampling	Bit Depth	Compression	Data rate	Audio Channels
HDV	1080 60i 1080 50i	1440 x 1080	4:2:0	8	MPEG-2	25 Mbps	2
	720 60p 720 50p 720 30p 720 24p	1280 x 720	4:2:0	8	MPEG-2	19.7 Mbps 19 Mbps	2
XDCAM HD	1080 60i 1080 50i 1080 30p 1080 25p 1080 24p	1440 x 1080	4:2:0	8	MPEG-2	Adjustable: 18 Mbps 25 Mbps 35 Mbps	4
D9-HD	1080 60i 720 24p	1280 x 1080 960 x 720	4:2:2	8	DCT	100 Mbps	8
DVCPRO HD (D12)	1080 60i 1080 50i 720 60p 720 50p	1280 x 1080 1440 x 1080 960 x 720	4:2:2	8	DCT	100 Mbps	8
D5 HD	1080 60i 1080 30p 1080 24p 720 60p	1920 x 1080   1280 x 720	4:2:2	8 10	DCT	235 Mbps	8
HDCAM (D11)	1080 60i 1080 50i 1080 25p 1080 24p	1440 x 1080	3:1:1	8	DCT	140 Mbps	4
HDCAM SR	1080i 60 1080i 50 1080PsF 30 1080PsF 29.97 1080PsF 25 1080PsF 24 1080PsF 23.98 720p	1920 x 1080	4:2:2 @ 440 Mbps 4:4:4 @ 880 Mbos	10	MPEG-4	440 Mbps	12

Editing

While linear, tape-to-tape based editing is still viable (and sometimes best suited for the job), most editors work with computer-based, non-linear editing systems. With dozens of vendors making HD-capable editing systems, there are many codecs available to choose from. Some codecs require proprietary hardware to use, while others are hardware independent. In addition to the standard bit depths of 8 and 10, there are also higher end, 16-bit codecs available from companies like Pinnacle and Digital Anarchy.

While HDTV is routinely compressed using MPEG-2 for transmission and delivery, uncompressed or mildly compressed data is preferred for editing. Since it’s often necessary for editors to composite many layers of content together in order to create special effects, it’s important to keep the signal as pristine as possible. This is why editors will often upconvert footage to a codec with better bit depth and higher resolution.

10-bit files contain more information than 8-bit files but also require more storage. Projects with demanding chromakeying or color compositing needs will be better served by codes with higher color sampling ratios (4:2:2 over 4:1:1, etc.). Similarly, compressed footage requires less bandwidth at the tradeoff of some quality loss. Lastly, choosing a lossless codec that operates in a 4:4:4 resolution will offer the highest quality but at the expense of requiring the greatest amount of storage.

Editing with personal computers in the production lab

HDV or MPEG-2 can be edited in its compressed form, but it's extremely processor-intensive. At 25 MBps it uses the same amount of bandwidth as DV, so users can easily use standard internal and external firewire drives for storage. Because of it's heavily compressed data structure, it's difficult to process video effects, such as color correction, and the entire sequence must be rendered or conformed before outputting to an HDV recorder. This can only be done via firewire interface. There are no HDV recorders at the time of this writing (11/2006) that accept HD component or HD-SDI- all use a firewire interface as the sole means for input.

DVCProHD aka DVCPro100 is an intraframe format, which in essence uses 4 streams of DV data. At 100 MBps, it's data can still fit on fast internal drives as well as external firewire drives. Some users have reportedly gotten up to 3-4 streams of DVCProHD from a single firewire800 external drive.

Booth 2 & 3 in the production lab are outfitted with AJA's Kona LHe cards that allow for HDV and DVCProHD acceleration and monitoring. While they have HD-SDI outputs, these are only utilized for monitoring.. We have no decks capable of real-time HD recording.

 

Other extra credit opportunities: Learn to edit HD and edit your own project. Will review today. Can facilitate this Thanksgiving week.

Reviewing Shorts

As mentioned earlier, we'll be reviewing the finished shorts the week after Thanksgiving. Everyone will be asked to write down and discuss elements that were working or not working. This will go to your participation score. Remember that you will be asked to include feedback from at least 8 different people.

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Production Meeting

 

 

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