Description of the Related Art Various devices have been developed to enable consumers to record video and/or audio programs for later presentation. Such devices include tape recorders, video cassette recorders, recordable compact disks, and most recently, recordable digital video disks (DVD). Hard drives and magneto optical disks have also been used. A DVD in which data can be recorded once only, and thereafter is essentially a DVD read only memory, is referred to by the acronym DVD-R. The acronym DVD-R also has been used generally to refer to write-once, or record-once, technology. In contrast to DVD-R, several formats exist in which data can be recorded to a DVD, erased and re-recorded. In sum, such a DVD can be overwritten or rewritten. These DVDs typically are referred to by the acronyms DVD-RAM, DVD-RW and DVD + RW. Although, as of this time no uniform industry standard has been adopted, the acronyms DVD-RAM, DVD-RW and DVD + RW have been used generally to refer to the respective rewritable technologies. Still, reference herein to re-writable DVD technology, devices and methods is generally intended to encompass all of the standards which are now being used, as well as those which may be developed in the future.

Present DVDs can have a logical file structure in which audio-video content can be stored. Specifically, as shown in Figure 5, at the top of the file structure hierarchy of a DVD 500, one or more titles 501 can exist which can loosely correlate to program episode titles. Titles 501 can consist of control data 502 in addition to one or more Video Object Sets 503 (VOBS). The control data 502 can contain information for managing the title 501. Each VOBS 503 can

include a plurality of Video Objects (VOB) 504. Each VOB 504 preferably inclues a plurality of Cells 505. Each Cell 505 preferably includes a plurality of Video Object Units (VOBU) 506. Each VOBU 506 roughly correlates to a group of pictures which is the smallest addressable chunk in the DVD 500.

Notably, each VOBU 506 can contain an integer number of video frames, typically 15 frames. As such, each VOBU 506 can contain 0.4 to 1.0 seconds of presentation material. A typical VOBU 506 in a commercial motion picture can contain 0.5 second of presentation material. Notably, each VOBU 506 can include a sequence of packs 507 positioned in recording order. Preferably, each VOBU can begin with a navigation pack 508 (NV-PCK or NAV-PACK) which can be followed by audio-visual data packs 509, for example video packs (VPCK), audio packs (A_PCK) and sub-picture packs (SPPCK). The NV-PCK 508 can contain navigation information, which can be useful in implementing trick modes of operation. The NV_PCK 508 also can include presentation control information (PCI) and data search information (DSI).

Although rewritable DVD technology is generally available, operation is limited to such basic functions as play, record, fast forward reverse and stop.

Pause is available, but only as a counterpart to pause operation in a VCR, for example interrupting the play back of a prerecorded program or interrupting the recording of a viewed program to eliminate commercials from the recording.

Unlike computer hard drives, recordable DVD devices have a very significant addition function, which is playing back prerecorded DVD's. Thus, there is an economic incentive to develop rewritable DVD technology, including methods and devices, that can be used instead of a computer hard drive. It is a challenge to provide such devices with improved, advantageous features without compromising the goal of decreasing costs and increasing sales. One feature which is important for recordable DVD is the ability for users to fade and mix pictures. Fading allows the image displayed for a video or still picture to slowly or rapidly fade in or fade out. Often, fading will be used at the beginning of a video segment, at the end of the segment or to transition from one segment to another. A fade effect generally involves completely fading out a video or still

picture image before fading in the next video or image. By comparison, mixing can include a video or still picture fading out as another video or still picture concurrently fades in. Fading and mixing allows consumers to make high quality home video. For example, fading and mixing allows smooth transitions from one video segment to the next. Since fading and mixing capabilities are not directly available in current recordable DVD systems, it is desirable to provide cost effective ways to implement such features.

SUMMARY OF THE INVENTION A method for providing a mixing effect in a recordable DVD player, can include several steps. In step (a), first and second decoded video bitstream frames can be provided to a mixer. In step (b), the first and second decoded video bitstream frames can be weighted. Specifically, the first decoded video bitstream frame is weighted according to a weighting coefficient Kn and the second decoded video bitstream frame is weighted according to the weighting coefficient (1-kan). In step (c), the weighted video bitstream frames can be mixed in the mixer. The mixing can form a combined video bitstream frame. Finally, in step (d), each of steps (a)- (c) can be repeated for successive pairs of first and second decoded video bitstream frames. Moreover, when repeating, the value of the weighting coefficient Kn can increase for each said successive pair of video bitstream frames. Notably, the combined video bitstream frame can be provided to a television display. Similarly, the combined video bitstream frame can be stored in a display buffer.

Different types of mixing can be desirable depending upon the situation when the mixing effect is used. For example mixing can involve a still picture fade-out as a video concurrently fades in, a video fade-out as a still picture fades in. As such, the providing step of the invention can include extracting from a video bitstream a decoded video bitstream frame; storing the decoded video bitstream frame in a still image buffer; and, providing the decoded video bitstream frame in the still image buffer and a subsequent decoded video bitstream frame in the decoded video bitstream to the mixer. In consequence,

the successive pairs of first and second decoded video bitstream frames comprises the first decoded video bitstream frame in the still image buffer and successive decoded video bitstream frames in the video bitstream.

Alternatively, mixing can involve a video fade-out as another video fades in. In this case, the providing step can include alternately decoding a frame in the first video bitstream and a frame in the second video bitstream; delaying providing the decoded frame from the first video bitstream to the mixer; and, concurrently providing to the mixer the decoded frame from the second video bitstream with the delayed decoded frame from the first video bitstream. In consequence, the successive pairs of first and second decoded video bitstream frames comprises successively delayed frames from the first decoded video bitstream and successively decoded frames from the second video bitstream.

Once the video bitstream frames have been mixed, the combined video bitstream can be re-encoded. More particularly, the re-encoding step can include MPEG encoding the combined video bitstream frame.

A mixing system in accordance with the inventive arrangements can include first and second decoded video bitstream frames; a weighting system for weighting the first and second decoded video bitstream frames; and, a mixer for concurrently mixing the weighted video bitstream frames, the mixing forming a combined video bitstream frame.

In this case, the first decoded video bitstream frame is weighted according to a weighting coefficient Kn and the second decoded video bitstream frame is weighted according to the weighting coefficient (1-Kn).

In one aspect of the invention, the system can further include a still image buffer for storing the first decoded video bitstream frame. Significantly, the still image buffer can provide the first decoded video bitstream frame concurrently with the second decoded video bitstream frame. In an alternative aspect of the invention, the system can include a delay block for delaying transmission of the first decoded video bitstream frame to the mixer. In this alternative aspect of the invention, the mixer can receive the second decoded video bitstream frame for mixing concurrently with receiving the delayed first decoded video bitstream frame.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a block diagram of a re-writable DVD device that can be provided with one or more advance operating features in accordance with the inventive arrangements.

Figure 2 is a schematic diagram of recordable DVD media.

Figure 3 is a block diagram in accordance with the inventive arrangements for a mixing feature where a still picture fades out as a video or motion picture concurrently fades in.

Figure 4 is a block diagram illustrating a system for producing the fading- out of one video bitstream while concurrently fading-in another video bitstream.

Figure 5 is a block diagram illustrating a DVD file hierarchy.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Recordable DVD Device A device 100 for implementing a method of disaster recovery for re- writable disk media in accordance with the inventive arrangements taught herein utilizes a recordable, re-writable disk medium 102 in accordance with the inventive arrangements is shown in block diagram form in Figure 1. The re- writable disk medium 102 is embodied as a re-writable DVD in the illustrated embodiment. In many instances, as will be noted, the re-writable disk medium can also be, for example, a hard drive or a magneto optical disk (MOD). An example of a MOD is a minidisk. In many instances, the inventive arrangements are applicable to video or audio or both video and audio.

The device 100 is capable of writing onto and reading from recordable DVD media, in this example, a re-writable DVD 102. The device comprises a mechanical assembly 104, a control section 120, a video/audio input processing path 140 and a video/audio output processing path 190. The allocation of most of the blocks to different sections or paths is self-evident, whereas the allocation of some of the blocks is made for purposes of convenience and is not critical to understanding the operation of the device.

The mechanical assembly 104 comprises a motor 106 for spinning the disk 102 and a pickup assembly 108 that is adapted to be moved over the spinning disk. The pickup 108 and the motor 106 are controlled by a servo 110.

The servo 110 can receive a playback signal of data which can be read from a spiral track of the disk 102 as a first input. The playback signal also can be an input to an error correction circuit 130, which can be considered part of the control section or part of the video/audio output processing path.

When reading data from the disk 102, a laser on the pickup assembly 108 can direct laser light at an interior layer surface of the disk 102. Depending upon the data stored on the disk 102, the laser light can be mostly reflected or mostly absorbed. The pickup assembly 108 can interpret reflected light as one type of electrical signal while light absorbed by the interior layer surface of the disk 102 can be interpreted as a second type of electrical signal. In the preferred embodiment, transitions between reflectivity and non-reflectivity are mapped to a digital signal referred to as the playback signal which corresponds to the data stored on the disk 102.

By comparison, during recording, a laser on the pickup assembly burns spots onto a spiral track on the disk 102 in order to digitally record video and/or audio program material. More particularly, the disk 102, which can include at least one interior crystalline recording layer, can exhibit two distinctive states, amorphous or crystalline, each having different reflectivity characteristics. Those different levels of reflectivity can be detected by optical sensors in the pickup assembly 108.

Prior to recording, the interior recording layer of the disk is in a crystalline state exhibiting high reflectivity. The light intensity of a laser beam can be modulated to write amorphous data marks on the surface of tracks in the interior crystalline recording layer. Specifically, the energy of a laser pulse can quickly raise the surface temperature of the interior crystalline recording layer above the layer melting point. Once above the melting point, the interior layer can transition from a crystalline state of high reflectivity to an amorphous state of low reflectivity. Subsequently, the rapid cooling of the layer prevents the

molecular structure of the interior layer from reorganizing into a crystalline state.

Hence, digital data can be mapped to a series of laser pulses which can write a digital code to the disk 102 which can correspond to the digital data.

Notably, depending upon capacity requirements, the disk 102 can have either one or two recordable sides. Additionally, the disk 102 can have multiple recordable layers per side. However, for purposes of understanding the invention, the number of sides and layers is irrelevant. Moreover, in the event of a double-sided recording, it also is irrelevant whether the recording of both sides of the disk 102 occurs from one or both sides of the disk 102.

Returning now to Figure 1, the control section 120 preferably comprises a controller 122 and a navigation data generation circuit 126. The controller 122 supplies a first input signal to the navigation data generation circuit 126 and the servo 110 supplies a second input signal to the navigation data generation circuit 126. The servo can also be considered part of the control section 120. The navigation data generation circuit 126 supplies a first input signal to the multiplexer (MUX) 154, which forms part of the video/audio input processing path 140. The output of the MUX 154 is an input to an error correction coding circuit 128. The output of the error correction coding circuit 128 is a recordable input signal supplied to the pickup 108, which will be"burned"onto the spiral track of the disk 102 by the laser.

The controller 122 also preferably has access to the data contained in the track buffer 172 and record buffer 152 as shown in Figure 1. The controller 122 can delete, modify, and reformat video data stored in the track buffer 172 and record buffer 152 for the purpose of implementing the inventive arrangements.

Control and data interfaces are also preferably provided for permitting the controller 122 to control the operation of packet video encoder 144 and audio encoder 148 for implementing the inventive embodiments as described herein.

Suitable software or firmware is provided in memory for the conventional operations performed by controller 122. In addition, program routines for the advanced features 134 are provided for controlling the controller 122 in accordance with the invention as shall hereinafter be described in greater detail.

A control buffer 132 for viewer activatable functions indicates those functions presently available, namely play, record, reverse, fast forward, pause/play and stop. The pause is a counterpart to pause operation in a VCR, for example manually interrupting the play back of a prerecorded program or interrupting the recording of a viewed program to eliminate commercials from the recording. A separate pause buffer 136 is provided to receive commands for performing the pause during record and playback function.

The video/audio input processing path 140 is a signal processing circuit for converting a conventional television signal, for example NTSC or PAL, into digitized packet data, for example MPEG-1 or MPEG-2, for digital recording by the device 100. The input path 140 comprises an NTSC decoder 142 and video encoder, for example MPEG-1 or MPEG-2,144 for video in, and comprises an audio analog-to-digital converter (A/D) 146 and an audio encoder, for example MPEG-1 or MPEG-2,148. The digitized signals are combined in a multiplexer 150 and stored in a record buffer 152 until an entire packet has been constructed. As each packet is constructed, each packet is combined with the output of the navigation data generation circuit in the MUX 154 and sent to the error correction coding circuit 128. Error correction coding circuit 128 can also be deemed to be part of the input path 140.

The output processing path 170 comprises a track buffer, or output buffer, 172, in which data read from the disk is assemble into packets for further processing. The packets are processed by conditional access circuit 174 that controls propagation of the packets through demultiplexer 176 and into respective paths for video and audio processing. The video is decoded by decoder 178, for example from MPEG-1 or MPEG-2, and encoded as a conventional television signal, for example NTSC or PAL. The audio is decoded by circuit 182, for example from MPEG-1 or MPEG-2, and converted to analog form by audio digital-to-analog (D/A) converter 184. The output processing path 170 can be deemed to include the error correction circuit 130, as noted.

Device 100 can represent a machine having, for example, a 1 X read and 1 X write capability. Such devices can typically have maximum data rates for

recording or playing back of approximately 11 megabits/second. In order to implement some of the inventive arrangements is necessary to play back (read) and record (write) in a manner that appears to be simultaneous. Apparently simultaneous playing back and recording with such a machine would seem to be impossible, but even such a minimal capability machine can be advantageously operated in accordance with the inventive arrangements to provide apparently simultaneous playing back and recording as well as other inventive arrangements.

It will also be appreciated that the inventive arrangements can also be useful for devices having higher data rates.

D VD Media For purposes of illustrating the inventive arrangements, program material can be recorded onto recordable DVD media, for example the re-writable DVD of Figure 1, and played back from the re-writable DVD. The re-writable DVD 102, as shown in further detail in Figure 2, can consist of two substrates bonded together by an adhesive layer forming a 1.2mm thick disk. A center hole 118 can be formed in the center of the disk so that a gripping device of the motor 106 of Figure 1 can securely grip the disk and control the angular motion of the same in accordance with the inventive arrangements.

As in convention DVD-RAM technology, the re-writable DVD 102 of the present invention incorporates a land/groove structure and phase change material to record data to disk. The land/groove combination forms a continuous spiral 112, with data recorded alternately on land and groove. Data can be written onto the re-writable DVD 102 in an outwardly direction along the spiral 112, beginning with the smaller radius portion of the spiral to the larger radius portion of the spiral 112. The several series of three large dots (-) denote portions of the spiral not shown in the drawing. Each nearly circular, radially concentric section of the spiral 112 is sometimes referred to as a track. Notably, the spiral 112 can be formed with a side-to-side wobble, not shown in the drawing, to accommodate media type indexing. Due to difficulties of scale only portions of the spiral 16 are shown, and these are shown in greatly enlarged scale.

To maintain constant data density across the surface of the re-writable DVD 102, the recording surface is divided into twenty-four (24) annular zones.

Each zone has 1,888 tracks, including 944 land tracks and 944 grove tracks.

Each track is divided into sectors 114 (only a single sector is shown for simplicity). The innermost zone has seventeen (17) sectors per track. The number of sectors per track increases by one in each succeeding zone. Hence, the outermost zone contains forty (40) sectors per track. Each sector 114 begins with a read-only identification field, embossed onto the disk surface. This identification field, known as the header, is used to identify the physical location of the sector and is kept separate from the user recordable data field, to assure that it is permanently readable. The re-writable DVD 102 can further include an embossed area 116 containing read-only data which can identify the type of media, for example DVD-RAM, DVD-ROM, or DVD-R.

It will be appreciated that the advanced features taught herein are applicable to other kinds of disk media and disk media players and recorders.

Additionally, various modifications of the device illustrated in Figure 1 and the disk medium illustrated in Figure 2 can be used together to implement the advanced features taught herein in accordance with the inventive arrangements.

In particular, those mixing features for a DVD recorder described herein in accordance with the inventive arrangements can include modifications of and additions to hardware, firmware and software in the controller 122 for recording data to recordable DVD media.

Mixing Features For A D VD Recorder DVD fading and mixing can be employed in a DVD recorder capable of processing DVD-RW, DVD-RAM, DVD + RW, etc. Specifically, mixing and fading features allow consumers to make high quality home videos which previously could be made only using professional recording equipment at the manufacturer level. In the present invention, video mixing can be performed with or without altering the DVD bit stream. The former technique, using altered DVD bit streams, can be performed in present DVD players. The latter technique, using unaltered DVD bit streams, can not be performed using present DVD players.

The inventive arrangements as described herein include methods for mixing operations using each of these techniques.

In general, mixing involves one of several known types of special effects which are particularly useful when programming video transitions. For instance, special effects can be used at the beginning of a video presentation (e. g., when transitioning from a title screen to video programming), at the end of a video presentation (e. g., when transitioning from the presentation to a list of redits), or during the presentation (e. g., when transitioning from one chapter to another).

Different types of mixing effects may be desirable depending upon the situation when the mixing effect is used. For example mixing can involve a still picture fade-out as a video concurrently fades in, a video fade-out as a still picture fades in, or a video fade-out as another video fades in. The inventive arrangements concern various techniques which can be used to implement each of the foregoing types of effects.

Still Picture Fade Out As A Video Concurrently Fades In Figure 3 is a block diagram in accordance with the inventive arrangements illustrating a system 300 for performing a still-picture fade-out as video concurrently fades in. In particular, the system 300 of Figure 3 can include an image buffer 304 for storing a still image and a packet video decoder 178 as previously described in relation to Fig. 1. However, rather than simply providing the output of the packet video decoder 178 to a TV encoder 180 as illustrated in Figure 1, the decoded output instead can be communicated to a mixer block 302 as shown in Figure 3. The mixer block 302 can perform video mixing of the decoded video from the packet video decoder 178 and the still image stored in the image buffer 304.

Video mixing block 302 can be any of a variety of well known arrangements for mixing video signals. Notably, the mixing block 302 can be a conventional video mixer which can be implemented in hardware, software, or a combination thereof as is well known to those skilled in the art. For example the mixer can be a linear type mixer which combines separate decoded MPEG video (digital or analog) to form a single image which is a combination thereof.

However, the mixer is not limited in this regard and any other suitable type video mixer can be used for this purpose.

In operation, as shown in Figure 3, upon activation of the mixing feature, the last picture in the previous video block or cell can be decoded in the packet video decoder 178 and stored in image buffer 304. Subsequently, video data contained in ensuing video blocks or cells can be decoded in the packet video decoder 178 and provided directly to the mixing block 302. The mixing block 302 can conventionally mix the still image in the image buffer 304 with individual pictures among the first several pictures provided directly from the packet video decoder 178. Initially, when mixing the still image with an individual picture, the mixing block can disproportionately weight the still image as compared to the individual picture. However, during each subsequent mixing of the still image with ensuing individual pictures, the weighting of the still image can decrease proportionately with an increase in the weighting of the individual pictures until the individual pictures are disproportionately weighted as compared to the still image.

For each mixing of a still picture with an individual picture, the above- described weighting can be performed by applying a mixing coefficient to each of the still picture and individual picture. Accordingly, the mixed picture Pn can be formed in accordance with the following rules : Pn Kn * PIB + (1-Kn) * Pnin when n < =N Pn = Pnin when n > N where Pn is the mixed picture output from the mixing block 302; Pie ils the picture from the image buffer; Pnin is the nif input picture received at the mixer from the packet video decoder 178; and Kn is a function of n. As illustrated by the foregoing rules, Kn serves as a mixing coefficient for determining the relative intensity of the pictures PIB and Pnin in the mixed picture output Pn.

Notably, the invention can be performed in an equally effective manner regardless of whether the still picture and fading video pictures are progressive or non-progressive frames. In particular, if the still picture is not a progressive frame, and the fading video pictures are not progressive frames, then the still

picture will be a field picture. If the following pictures are progressive frames, then the still picture is a frame with two identical fields. If the still picture is a progressive frame, then it will mix with the same parity field of the fading-in video pictures.

Once produced, the mixed picture Pn can be provided to a display buffer 306 or directly to a TV encoder 180 as shown in Figure 1. Once N pictures have been processed, the still picture will have been completely faded out as the value Kn will have become disproportionately small as compared to the value 1-Kn.

Thus, the video will have completely faded in. Notably, because the mixing is performed in an uncompressed domain following MPEG decoding and post- processing of the video signal read from the recordable medium 102, the compressed DVD bit stream remains unaltered. Significantly, the number N can be defined according to the desired fading time and the target signal format. For example, if the desired fading time is 2 seconds and the target signal format is NTSC, then N = 30 frames/second * 2 seconds = 60 frames.

Figure 3 shows one possible implementation for the fading feature as described herein. However, it will be appreciated that the invention is not limited in this regard. For example, the fading can also be done by mixing the still picture and the video and re-encoding the combined picture. In that case, instead of providing the combined signal to a TV encoder 180 as shown in Figure 1, the mixing block 302 can provide the combined signal to a packet or MPEG video encoder for re-encoding the combined picture in the MPEG format.

Video Fade Out as Another Video Fades In In order to create a mixing effect whereby a first video fades out as another video fades in, it is generally necessary to concurrently provide a conventional mixer with both video signals. At present, a packet video decoder cannot decode two video bitstreams simultaneously. However, some segments of the two video bitstreams can be re-encoded to obtain video fading. Assuming that two video bitstreams are recorded on a DVD, and the two video bitstreams are stored in two adjacent cells or in the same cell, in accordance with the inventive arrangements, these two video bitstreams can be decoded, mixed and

re-encoded. When two video bitstreams are mixed, the display time can be less than the sum of that of the two video bitstreams. The end result can make the re-encoded video bitstream smaller in total bit count than the sum of original two video bitstreams.

Figure 4 is a block diagram illustrating a system 400 for fading-out one video bitstream while concurrently fading-in another video bitstream. The system 400 as illustrated in Figure 4 can be used to perform concurrent fading-in and fading-out when reading two video bitstreams 410,420 from a single recordable medium such as the re-writable disc 102 of Figure 1. In particular, single frames from a first video bitstream 410 and a second video bitstream 420 alternately can be decoded and provided to the mixing block 402. Each frame from the first video bitstream 410, however can be delayed such that the frame from the first video bitstream 410 can be presented to the mixing block 402 concurrently with a frame from the second video bitstream 420. As in the mixing block 302 of Figure 3, the mixing block 402 of Figure 4 can mix the two frames weighting each according to the mixing coefficient Kn. Subsequently, the combined picture produced by the mixing block 402 can be provided to an encoder buffer 406 from which an encoder 408, for example an MPEG encoder, can re-encode the combined frame. Notably, the re-encoded combined frame can be written to a re-writable disc. Still, the invention is not limited in regard to the use of the mixed frames. Rather, in other aspects of the invention, the mixed frames can be provided to a display buffer for ultimate display in a video display terminal or television.

As illustrated in Figure 4, two separate video bitstreams 410,420 can be provided to the system 400. Switch s1 and switch s2 can be coordinated to alternately provide the video bitstreams 410,420 to a packet video decoder such as the packet video decoder 178 of Figure 1. While the second video bitstream 420 can be decoded in the packet video decoder 178 and provided to the mixing block 402, the first video bitstream 410 can be provided to a delay block 403.

The delay block 403 can hold a frame of the first video bitstream 410 for a delay period prior to providing the same to the mixing block 402 concurrently with the

provision of a frame from the second video bitstream 420 to the mixing block 402. In one aspect of the present invention, the delay period can correspond to a frame period.

As in the case of Figure 3, the mixing block 402 of Figure 4 can conventionally mix the delayed frame of the first video bitstream 410 with a frame of the second video bitstream 420. Initially, when mixing the delayed frame of the first video bitstream 410 with a frame of the second video bitstream, the mixing block 402 can disproportionately weight the delayed frame of the first video bitstream 410 compared to the frame of the second video bitstream 420. However, during each subsequent mixing of a delayed frame of the first video bitstream 410 with a frame of the second video bitstream 420, the weighting of the delayed frames of the first video bitstream 410 can decrease proportionately with an increase in the weighting of the frames of the second video bitstream 420 until the frames of the second video bitstream 420 are disproportionately weighted as compared to the delayed frames. Thus, a mixing effect can be produced whereby the first video bitstream fades out as the second video bitstream fades in.

CLAIMS : 1. A method for providing a mixing effect in a recordable DVD player, comprising: (a) providing first and second decoded video bitstream frames to a mixer; (b) weighting said first and second decoded video bitstream frames wherein said first decoded video bitstream frame is weighted according to a weighting coefficient Kn and said second decoded video bitstream frame is weighted according to a weighting coefficient (1-Kn) ; (c) mixing in said mixer said weighted video bitstream frames, said mixing forming a combined video bitstream frame; and, (d) repeating steps (a)- (c) for successive pairs of first and second decoded video bitstream frames, wherein said weighting coefficient Kn increases in value for each said successive pair of video bitstream frames.

2. The method of claim 1, wherein said providing step comprises: extracting from a video bitstream a decoded video bitstream frame; storing said decoded video bitstream frame in a still image buffer; and, providing said decoded video bitstream frame in said still image buffer and a subsequent decoded video bitstream frame in said decoded video bitstream to said mixer; wherein said successive pairs of first and second decoded video bitstream frames comprises said first decoded video bitstream frame in said still image buffer and successive decoded video bitstream frames in said video bitstream.

3. The method of claim 1, wherein said providing step comprises: alternately decoding a frame in said first video bitstream and a frame in said second video bitstream; delaying said providing of said decoded frame from said first video bitstream to said mixer; and,

concurrently providing to said mixer said decoded frame from said second video bitstream and said delayed decoded frame from said first video bitstream; wherein said successive pairs of first and second decoded video bitstream frames comprises successively delayed frames from said first decoded video bitstream and successively decoded frames from said second video bitstream.

4. The method of claim 2, further comprising: providing said combined video bitstream frame to a television display.

5. The method of claim 2, further comprising: storing said combined video bitstream frame in a display buffer.

6. The method of claim 3, further comprising: re-encoding said combined video bitstream frame.

7. The method of claim 6, wherein said re-encoding step comprises: MPEG encoding said combined video bitstream frame.

8. A mixing system comprising: first and second decoded video bitstream frames; a weighting system for weighting said first and second decoded video bitstream frames wherein said first decoded video bitstream frame is weighted according to a weighting coefficient Kn and said second decoded video bitstream frame is weighted according to a weighting coefficient (1-Kn) ; and, a mixer for concurrently mixing said weighted video bitstream frames, said mixing forming a combined video bitstream frame.

9. The system of claim 8, further comprising: a still image buffer for storing said first decoded video bitstream frame, said still image buffer providing said first decoded video bitstream frame concurrently with said second decoded video bitstream frame.

10. The system of claim 8, further comprising: a delay block for delaying transmission of said first decoded video bitstream frame to said mixer, said mixer receiving said second decoded video bitstream frame for mixing concurrently with receiving said delayed first decoded video bitstream frame.

11. A machine readable storage having stored thereon, a computer program having a plurality of code sections for providing a mixing effect in a recordable DVD player, said code sections executable by a machine for causing the machine to perform the steps of: (a) providing first and second decoded video bitstream frames to a mixer; (b) weighting said first and second decoded video bitstream frames wherein said first decoded video bitstream frame is weighted according to a weighting coefficient Kn and said second decoded video bitstream frame is weighted according to a weighting coefficient (1-Kn) ; (c) mixing in said mixer said weighted video bitstream frames, said mixing forming a combined video bitstream frame; and, (d) repeating steps (a)- (c) for successive pairs of first and second decoded video bitstream frames, wherein said weighting coefficient Kn increases in value for each said successive pair of video bitstream frames.

12. The machine readable storage of claim 11, wherein said providing step comprises : extracting from a video bitstream a decoded video bitstream frame; storing said decoded video bitstream frame in a still image buffer; and, providing said decoded video bitstream frame in said still image buffer and a subsequent decoded video bitstream frame in said decoded video bitstream to said mixer ;

wherein said successive pairs of first and second decoded video bitstream frames comprises said first decoded video bitstream frame in said still image buffer and successive decoded video bitstream frames in said video bitstream.

13. The machine readable storage of claim 11, wherein said providing step comprises: alternately decoding a frame in said first video bitstream and a frame in said second video bitstream; delaying said providing of said decoded frame from said first video bitstream to said mixer; and, concurrently providing to said mixer said decoded frame from said second video bitstream and said delayed decoded frame from said first video bitstream; wherein said successive pairs of first and second decoded video bitstream frames comprises successively delayed frames from said first decoded video bitstream and successively decoded frames from said second video bitstream.

14. The machine readable storage of claim 12, further comprising: providing said combined video bitstream frame to a television display.

15. The machine readable storage of claim 12, further comprising: storing said combined video bitstream frame in a display buffer.

16. The machine readable storage of claim 13, further comprising: re-encoding said combined video bitstream frame.

17. The machine readable storage of claim 16, wherein said re-encoding step comprises: MPEG encoding said combined video bitstream frame.