초록 ▼

A lossless image streaming system for the transmission of images over a communication network. The system eliminates the necessity to store a compressed version of the original image, by losslessly streaming ROI data using the original stored image. The imaging system also avoids the computationally

A lossless image streaming system for the transmission of images over a communication network. The system eliminates the necessity to store a compressed version of the original image, by losslessly streaming ROI data using the original stored image. The imaging system also avoids the computationally intensive task of compression of the full image. When a user wishes to interact with a remote image, the imaging client generates and sends a ROI request list to the imaging server. The request list can be ordered according to the particular progressive mode selected (e.g., progressive by quality, resolution or spatial order). The imaging server performs a fast preprocessing step in near real time after which it can respond to any ROI requests in near real time. When a ROI request arrives at the server, a sophisticated progressive image encoding algorithm is performed, but not for the full image. Instead, the encoding algorithm is performed only for the ROI. Since the size of the ROI is bounded by the size and resolution of the viewing device at the client and not by the size of the image, only a small portion of the full progressive coding computation is performed for a local area of the original image.

대표청구항 ▼

What is claimed: 1. A system for lossless progressive streaming of images over a communication network, comprising: an image storage device for storing a digital image; a client computer coupled to the communication network, wherein said client computer generates and transmits across said communica

What is claimed: 1. A system for lossless progressive streaming of images over a communication network, comprising: an image storage device for storing a digital image; a client computer coupled to the communication network, wherein said client computer generates and transmits across said communication network a request list containing the coordinates of data blocks required for rendering a region of interest (ROI) within said digital image, wherein said request list is ordered in accordance with a selected progressive mode; a server computer coupled to said communication network and said image storage device, said server computer adapted to perform the steps of: preprocessing said digital image through a low pass filter and a lossless wavelet transform to yield low pass scaling function data, high pass wavelet coefficient data and halfbit data; receiving said request list from said client computer; progressively transmitting to said client computer subband coefficient data blocks corresponding to said region of interest in the order they were requested, said subband coefficient data blocks defined by said coordinates and determined in accordance with said wavelet coefficients and said half-bit matrix; wherein said lossless wavelet transform comprises the steps of: first applying an X-direction wavelet transform to the output of said low pass filter to yield a temporal matrix therefrom; second applying a low Y-direction wavelet transform to a low portion of said temporal matrix to yield LL and LH subband coefficients; and third applying a high Y-direction wavelet transform to a high portion of said temporal matrix to yield HL and HH subband coefficients including a half-bit matrix containing half-bits, each half-bit corresponding to an HH subband coefficient. 2. A server for lossless progressive streaming of images to a client over a communication network, comprising: an image storage device for storing a digital image; a processor in communication with said image storage device and adapted to perform the steps of: preprocessing said digital image through a low pass filter and a lossless wavelet transform a predetermined number of times to yield low pass scaling function data, high pass wavelet coefficient data and halfbit data; storing said low pass scaling function data, said high pass wavelet coefficient data and said halfbit data in a memory cache; receiving a request for one or more data blocks from said client, each data block corresponding to a region of interest; if a requested data block is not present in said memory cache, performing said step of preprocessing on a minimum portion of the region of interest requiring processing; transmitting to said client computer subband coefficient data blocks corresponding to said region of interest; wherein said lossless wavelet transform comprises the steps of: first applying an X-direction wavelet transform to the output of said low pass filter to yield a temporal matrix therefrom; second applying a low Y-direction wavelet transform to a low portion of said temporal matrix to yield LL and LH subband coefficients; and third applying a high Y-direction wavelet transform to a high portion of said temporal matrix to yield HL and HH subband coefficients including a half-bit matrix containing half-bits, each half-bit corresponding to an HH subband coefficient. 3. A 2D wavelet transform method for use on a server for providing lossless progressive streaming of images to a client over a communication network, said server in communication with an image storage device for storing digital images, said method comprising the steps of: first applying an X-direction wavelet transform to a digital image to yield a temporal matrix therefrom; second applying a low Y-direction wavelet transform to a low portion of said temporal matrix to yield LL and LH subband coefficients; and third applying a high Y-direction wavelet transform to a high portion of said temporal matrix to yield HL and HH subband coefficients including a half-bit matrix containing half-bits, each half-bit corresponding to an HH subband coefficient. 4. The method according to claim 3, wherein said X-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n) and d(n) represents the difference between s(n) and x(n). 5. The method according to claim 3, wherein said low Y-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n), and d(n) and d(1)(n) represent differences between s(n) and x(n). 6. The method according to claim 5, wherein bits able to be known a priori to a decoder are not encoded. 7. The method according to claim 5, wherein the least significant bit of d(n) is always zero and not encoded. 8. The method according to claim 3, wherein said high Y-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n), d(n) and d(1)(n) represent differences between s(n) and x(n) and Halfbit(n) represents said half-bits. 9. The method according to claim 3, wherein said X-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n), and d(n) and d(1)(n) represent differences between s(n) and x(n). 10. The method according to claim 3, wherein said low Y-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n), and d(n) and d(1)(n) represent differences between s(n) and x(n). 11. The method according to claim 10, wherein bits able to be known a priori to a decoder are not encoded. 12. The method according to claim 10, wherein the least significant bit of d(n) is always zero and not encoded. 13. The method according to claim 3, wherein said high Y-direction wavelet transform comprises wherein x(n) is the original image; s(n) is a low resolution version of x(n), d(n) and d(1)(n) represent differences between s(n) and x(n) and HalfBit(n) represents said half-bits.