1. A method for decompressing image data, the method comprising:
receiving, from an image sensor chip, compressed pixel data, the compressed pixel data comprising pixel data organized into a plurality categories and compressed in parallel by the image sensor chip at a magnitude of compression selected based on one or more of a rate at which the pixel data is captured and an amount of power available to the image sensor chip;
decompressing, by a digital signal processor (DSP), the compressed pixel data to produce decompressed pixel data organized into the plurality of categories;
combining the categories of decompressed pixel data to produce combined pixel data;
compressing the combined pixel data to produce a digital image comprising a digital image format; and
outputting the digital image.
2. The method of claim 1, wherein each pixel of the decompressed pixel data is organized into a plurality of categories comprising a) either odd column pixel data or even column pixel data, and b) either odd row pixel data or even row pixel data.
3. The method of claim 2, wherein combining the categories of decompressed pixel data comprises interleaving pixel data comprising odd column pixel data and pixel data comprising even column pixel data, and interleaving pixel data comprising odd row pixel data and pixel data comprising even row pixel data.
4. The method of claim 1, wherein the decompressed pixel data is organized into a plurality of categories comprising red pixel data, blue pixel data, a first portion of green pixel data, and a second portion of green pixel data.
5. The method of claim 4, wherein combining the categories of decompressed pixel data comprises forming a combined pixel, the combined pixel comprising a pixel of the red pixel data, a pixel of the blue pixel data, a pixel of the first portion of green pixel data, and a pixel of the second portion of the green pixel data.
6. A digital signal processor (DSP) comprising an instruction set that, when executed, causes the DSP to perform steps comprising:
receiving, from an image sensor chip, compressed pixel data, the compressed pixel data comprising pixel data organized into a plurality categories and compressed in parallel by the image sensor chip at a magnitude of compression selected based on one or more of a rate at which the pixel data is captured and an amount of power available to the image sensor chip;
decompressing the compressed pixel data to produce decompressed pixel data organized into the plurality of categories;
combining the categories of decompressed pixel data to produce combined pixel data;
compressing the combined pixel data to produce a digital image comprising a digital image format; and
outputting the digital image.
7. The DSP of claim 6, wherein each pixel of the decompressed pixel data is organized into a plurality of categories comprising a) either odd column pixel data or even column pixel data, and b) either odd row pixel data or even row pixel data.
8. The DSP of claim 7, wherein combining the categories of decompressed pixel data comprises interleaving pixel data comprising odd column pixel data and pixel data comprising even column pixel data, and interleaving pixel data comprising odd row pixel data and pixel data comprising even row pixel data.
9. The DSP of claim 6, wherein the decompressed pixel data is organized into a plurality of categories comprising red pixel data, blue pixel data, a first portion of green pixel data, and a second portion of green pixel data.
10. The DSP of claim 9, wherein combining the categories of decompressed pixel data comprises forming a combined pixel, the combined pixel comprising a pixel of the red pixel data, a pixel of the blue pixel data, a pixel of the first portion of green pixel data, and a pixel of the second portion of the green pixel data.
11. A method for decompressing image data, the method comprising:
receiving, from an image sensor chip, compressed pixel data, the compressed pixel data comprising pixel data organized into a plurality categories and compressed;
decompressing, by a digital signal processor (DSP), the compressed pixel data to produce decompressed pixel data organized into the plurality of categories;
combining the categories of decompressed pixel data to produce combined pixel data; and
processing the combined pixel data to produce a digital image.
12. The method of claim 11, wherein each pixel of the decompressed pixel data is organized into a plurality of categories comprising a) either odd column pixel data or even column pixel data, and b) either odd row pixel data or even row pixel data.
13. The method of claim 12, wherein combining the categories of decompressed pixel data comprises interleaving pixel data comprising odd column pixel data and pixel data comprising even column pixel data, and interleaving pixel data comprising odd row pixel data and pixel data comprising even row pixel data.
14. The method of claim 11, wherein the decompressed pixel data is organized into a plurality of categories comprising red pixel data, blue pixel data, a first portion of green pixel data, and a second portion of green pixel data.
15. The method of claim 14, wherein combining the categories of decompressed pixel data comprises forming a combined pixel, the combined pixel comprising a pixel of the red pixel data, a pixel of the blue pixel data, a pixel of the first portion of green pixel data, and a pixel of the second portion of the green pixel data.
16. A digital signal processor (DSP) comprising an instruction set that, when executed, causes the DSP to perform steps comprising:
receiving, from an image sensor chip, compressed pixel data, the compressed pixel data comprising pixel data organized into a plurality categories and compressed;
decompressing the compressed pixel data to produce decompressed pixel data organized into the plurality of categories;
combining the categories of decompressed pixel data to produce combined pixel data; and
processing the combined pixel data to produce a digital image.
17. The DSP of claim 16, wherein each pixel of the decompressed pixel data is organized into a plurality of categories comprising a) either odd column pixel data or even column pixel data, and b) either odd row pixel data or even row pixel data.
18. The DSP of claim 17, wherein combining the categories of decompressed pixel data comprises interleaving pixel data comprising odd column pixel data and pixel data comprising even column pixel data, and interleaving pixel data comprising odd row pixel data and pixel data comprising even row pixel data.
19. The DSP of claim 16, wherein the decompressed pixel data is organized into a plurality of categories comprising red pixel data, blue pixel data, a first portion of green pixel data, and a second portion of green pixel data.
20. The DSP of claim 19, wherein combining the categories of decompressed pixel data comprises forming a combined pixel, the combined pixel comprising a pixel of the red pixel data, a pixel of the blue pixel data, a pixel of the first portion of green pixel data, and a pixel of the second portion of the green pixel data.
The claims below are in addition to those above.
All refrences to claims which appear below refer to the numbering after this setence.
1. An electric submersible pumping system comprising:
a pump;
an electric motor coupled to the pump, the electric motor having a stator containing a plurality of slots;
magnet wires threaded within various ones of the slots for each phase of the motor, each of the magnet wires having at least one insulation layer formed of a polyimide;
an epoxy surrounding and bonding the magnet wires within the slots;
a dielectric poly alpha olefin (PAO) lubricant contained in the motor; and
a buffer in the lubricant for dissipating amino acid generated by the epoxy within the motor.
2. The system of claim 1, further comprising:
a slot insulation surrounding all of the magnet wires within each of the slots; and wherein the slot insulation comprises:
a sheet of polyimide film.
3. The system of claim 2, wherein the sheet of polyimide film is sandwiched between inner and outer sheets of polymeric films that differ from the polyimide film.
4. The system of claim 3, wherein the slot insulation further comprises:
an inner sheet of polyether ether ketone (PEEK) film; and
an outer sheet of polytetrafluoroethylene (PTFE) film, with the polyimide film being sandwiched between.
5. The system of claim 1, wherein:
the magnet wires protrude past the lower end of the stator in loops positioned around an end bell area; and
an end bell insulation surrounds all of the loops and comprises a sheet of polyimide film formed in the shape of a sleeve.
6. The system of claim 5, wherein the sheet of polyimide film is sandwiched between inner and outer sheets of polymeric films that differ from the polyimide film.
7. The system of claim 6, wherein each of the inner and outer sheets comprises polytetrafluoroethylene (PTFE) film.
8. The system of claim 5, wherein:
the loops of magnet wire are grouped into three phases, each of the phases being positioned at a different distance from a longitudinal axis of the motor; and wherein the system further comprises:
a phase-to-phase insulation sheet formed as a cylinder and located between each of the phases of magnet wire loops; and
each of the phase-to-phase insulation sheets comprises a polyimide film.
9. The system of claim 8, wherein:
each of the sheets of polyimide film is sandwiched between inner and outer sheets of polymeric films that differ from the polyimide film.
10. The system of claim 9, wherein each of the inner and outer sheets comprise polytetrafluoroethylene (PTFE) film.
11. The system of claim 1, further comprising:
a motor housing receptacle to which the connector of the power cable assembly releasably attaches, the receptacle having a plurality of internal electrical contacts; wherein
each of the magnet wires within the slots of the stator has an upper portion extending above the stator with an upper end configured as an electrical terminal that releasably attaches to one of the internal electrical contacts, each of the magnet wires within the slots of the stator being a continuous wire without splices from a lower end below the stator to the electrical terminal; and wherein the system further comprises:
at least one tube formed of an insulation material surrounding but not bonded to the insulation layer on each of the motor leads, the at least one tube having a lower end at an upper end of the stator and an upper end at the receptacle.
12. The system of claim 1, wherein:
the magnet wires are joined to each other below the stator, defining a Y-point connection; and
an insulation tape is wrapped around the Y-point connection, the insulation tape comprising a polyimide film.
13. The system according to claim 1, wherein at least some of the insulation on the magnet wires is immersed in the lubricant.
14. An electric submersible pumping system comprising:
a pump;
an electric motor coupled to the pump, the electric motor having a stator containing a plurality of slots;
a poly alpha olefin (PAO) lubricant contained in the motor;
a seal and equalizer section located between the pump and the motor for reducing a pressure differential between the lubricant in the motor and wellbore fluids on an exterior of the motor;
magnet wires threaded within various ones of the slots for each phase of the motor, each of the magnet wires having at least one insulation layer formed of a polyimide;
an epoxy surrounding and bonding the magnet wires within the slots;
a slot insulation comprising a sheet of polyimide film surrounding all of the magnet wires within each of the slots; and
a buffer contained in the lubricant for dissipating amino acid generated by the epoxy to avoid damage to the insulation layer on the magnet wires and the slot insulation.
15. The system of claim 14, wherein:
the magnet wires protrude past a lower end of the stator in loops positioned around an end bell area; and
an end bell insulation surrounds all of the loops and comprises a sheet of polyimide film formed in the shape of a sleeve.
16. The system of claim 15, wherein:
the loops of magnet wire are grouped into three phases, each of the phases being positioned at a different distance from a longitudinal axis of the motor; and wherein the system further comprises:
a phase-to-phase insulation sheet formed as a cylinder and located between each of the phases of magnet wire loops; and
each of the phase-to-phase insulation sheets comprises a polyimide film.
17. An electric submersible pumping system comprising:
a pump;
an electric motor coupled to the pump;
a power lead receptacle mounted to a housing of the motor;
the motor having a stator having a plurality of slots, each of the slots having a bundle of magnet wires;
a polyimide film adhered to a conductor of each of the magnet wires by adhesive;
each of the magnet wires extending above the stator and having an electrical terminal on an upper end that releasably connects to the receptacle, each of the magnet wires extending through selected ones of the slots to the electrical terminal without any splices;
a plurality of tubes formed of an insulation material and having a lower end at an upper end of the stator and an upper end at the receptacle, each of the tubes surrounding one of the magnet wires;
a slot insulation surrounding at least a portion of each of the bundles in the slots, the slot insulation comprising a sheet of polyimide film;
an end bell area on a lower end of the stator where the magnet wires protrude past the lower end of the stator in loops, the loops of magnet wire being grouped into phases;
an end bell insulation sleeve comprising a sheet of polyimide extending around the loops of magnet wire; and
inner and outer phase-to-phase insulation sleeves extending between each of the phases, each of the cylinders comprising a sheet of a polyimide;
a poly alpha olefin (PAO) lubricant contained in the motor; and
an acid dissipating buffering additive contained in the lubricant.
18. The system of claim 17, wherein the lubricant is free to flow into each of the tubes into contact with the polyimide film of each of the magnet wires located in the tubes.
19. The system of claim 17, wherein:
the polyimide film surrounding the conductor of each of the magnet wires comprises a tape with inner and outer adhesive layers, the tape having a first wrap wrapped helically around the conductor in a first direction, and a second wrap wrapped helically around the first wrap in a second direction;
the outer adhesive layer of the first wrap is bonded to the inner adhesive layer of the second wrap; and
the outer adhesive layer of the second wrap is free of bonding engagement with the tube in which it is contained.
20. The system of claim 17, wherein:
the magnet wires are joined to each other below the stator, defining a Y-point connection; and
an insulation tape is wrapped around the Y-point connection, the insulation tape comprising a polyimide film and being immersed in the lubricant.