X-ray source and method having cathode with curved emission surface
First Claim
Patent Images
1. An X-ray source comprising:
- a cold cathode, the cold cathode having a curved emission surface capable of emitting electrons; and
an anode, the anode being spaced apart from the cathode, the anode being capable of emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface;
wherein the cold cathode comprises a plurality of emitters disposed on a substrate and a gate conductor disposed adjacent the plurality of emitters, and wherein the plurality of emitters are operative to emit electrons when a bias voltage is applied to the gate conductor;
wherein the electrons bombard the anode at a focal spot of the anode, wherein the plurality of emitters comprises a first set of emitters, the first set of emitters being operative to emit a first electron beam having a first focal spot with a first shape, and a second set of emitters, the second set of emitters being operative to emit a second electron beam having a second focal spot with a second shape, the second shape being different than the first shape, and wherein the first set of emitters and the second set of emitters are located on the same curved emission surface and are separately energizable.
1 Assignment
0 Petitions
Accused Products
Abstract
An X-ray source comprises a cold cathode and an anode. The cold cathode has a curved emission surface capable of emitting electrons. The anode is spaced apart from the cathode. The anode is capable of emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface of the cathode.
-
Citations
31 Claims
-
1. An X-ray source comprising:
-
a cold cathode, the cold cathode having a curved emission surface capable of emitting electrons; and
an anode, the anode being spaced apart from the cathode, the anode being capable of emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface;
wherein the cold cathode comprises a plurality of emitters disposed on a substrate and a gate conductor disposed adjacent the plurality of emitters, and wherein the plurality of emitters are operative to emit electrons when a bias voltage is applied to the gate conductor;
wherein the electrons bombard the anode at a focal spot of the anode, wherein the plurality of emitters comprises a first set of emitters, the first set of emitters being operative to emit a first electron beam having a first focal spot with a first shape, and a second set of emitters, the second set of emitters being operative to emit a second electron beam having a second focal spot with a second shape, the second shape being different than the first shape, and wherein the first set of emitters and the second set of emitters are located on the same curved emission surface and are separately energizable. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
-
-
12. An imaging system for imaging an object of interest, the imaging system comprising:
-
(A) an X-ray source, the X-ray source including (1) a cold cathode disposed within a housing, the cold cathode having a curved emission surface, the cold cathode comprising a plurality of emitters disposed on a substrate, and (2) an anode, the anode being disposed within the housing and spaced apart from the cathode, the anode emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface wherein the electrons bombard the anode at a focal spot of the anode;
(B) a detector array, the detector array comprising a plurality of detector elements, the plurality of detector elements receiving the X-rays after the X-rays pass through the object of interest and generating signals in response thereto;
(C) an image reconstructor, the image reconstructor being coupled to receive the signals from the detector elements, and the image reconstructor constructing an image of the object of interest based on the signals from the detector elements;
(D) a display, the display being coupled to the image reconstructor, and the display displaying the image of the object of interest; and
(E) an X-ray controller, the X-ray controller being coupled to the cold cathode to provide control signals to control the emission of electrons from the plurality of emitters, the X-ray controller being coupled to receive feedback information pertaining to the operation of the imaging system, and wherein the X-ray controller adjusts the control signals for the plurality of emitters as a function of the feedback information. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22)
an insulative layer, the insulative layer being disposed on the substrate and being located between the plurality of emitters; a gate conductor, the gate conductor being disposed on the insulative layer; and
wherein the plurality of emitters are operative to emit electrons when a bias voltage is applied to the gate conductor.
-
-
17. An imaging system according to claim 12, wherein the imaging system is a computed tomography imaging system, wherein the system further comprises a plurality of additional X-ray sources, the plurality of additional X-ray sources each comprising a respective additional cold cathode and a respective additional anode, wherein the X-ray source and the plurality of additional X-ray sources are disposed in a ring so as to permit the object of interest to be imaged without gantry rotation.
-
18. An imaging system according to claim 17, wherein the system further comprises an X-ray controller, and wherein the X-ray controller sequentially activates the X-ray source and the plurality of additional X-ray sources in a manner that simulates rotation of a single X-ray source about the object of interest.
-
19. An imaging system according to claim 12, wherein the imaging system is a medical imaging system.
-
20. An imaging system according to claim 12, wherein the imaging system is a security checkpoint imaging system.
-
21. A imaging system according to claim 12, further comprising a communication interface, the communication interface being coupled to the image reconstructor, and wherein the communication interface transmits the image of the object of interest over a communication network.
-
22. A imaging system according to claim 12, further comprising a communication interface, the communication interface being coupled to the X-ray controller constructor, the communication interface transmitting data pertaining to the health and operation of the imaging system on a communication network.
-
23. An imaging system for imaging an object of interest, the imaging system comprising:
-
(A) an X-ray source, the X-ray source including (1) a cold cathode disposed within a housing, the cold cathode having a curved emission surface, the cold cathode comprising a plurality of emitters disposed on a substrate, and (2) an anode, the anode being disposed within the housing and spaced apart from the cathode, the anode emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface;
(B) a detector array, the detector array comprising a plurality of detector elements, the plurality of detector elements receiving the X-rays after the X-rays pass through the object of interest and generating signals in response thereto;
(C) an image reconstructor, the image reconstructor being coupled to receive the signals from the detector elements and the image reconstructor constructing an image of the object of interest based on the signals from the detector elements; and
(D) a display, the display being coupled to the image reconstructor, and the display displaying the image of the object of interest (E) an X-ray controller, the X-ray controller being coupled to the cold cathode to provide control signals to control the emission of electrons from the plurality of emitters, wherein the electrons bombard the anode at a focal spot of the anode and wherein the X-ray controller adjusts the control signals for the plurality of emitters to control a size and shape of the focal spot. - View Dependent Claims (24, 25, 26, 27, 28)
an insulative layer, the insulative layer being disposed on the substrate and being located between the plurality of emitters; a gate conductor, the gate conductor being disposed on the insulative layer; and
wherein the plurality of emitters are operative to emit electrons when a bias voltage is applied to the gate conductor.
-
-
26. An imaging system according to claim 23, wherein the imaging system is a computed tomography imaging system, wherein the system further comprises a plurality of additional X-ray sources, the plurality of additional X-ray sources each comprising a respective additional cold cathode and a respective additional anode, wherein the X-ray source and the plurality of additional X-ray sources are disposed in a ring so as to permit the object of interest to be imaged without gantry rotation.
-
27. An imaging system according to claim 23, wherein the imaging system is a medical imaging system.
-
28. A imaging system according to claim 23, further comprising a communication interface, the communication interface being coupled to the image reconstructor, and wherein the communication interface transmits the image of the object of interest over a communication network.
-
29. An imaging system for imaging an object of interest, the imaging system comprising:
-
(A) an X-ray source, the X-ray source including (1) a cold cathode disposed within a housing, the cold cathode having a curved emission surface, the cold cathode comprising a plurality of emitters disposed on a substrate, and (2) an anode, the anode being disposed within the housing and spaced apart from the cathode, the anode emitting X-rays in response to being bombarded with electrons emitted from the curved emission surface;
(B) a detector array, the detect array comprising a plurality of detector elements, the plurality of detector elements receiving the X-rays after the X-rays pass through the object of interest and generating signals in response thereto;
(C) an image reconstructor, the image reconstructor being coupled to receive the signals from the detector elements, and the image reconstructor constructing an image of the object of interest based on the signals from the detector elements; and
(D) a display, the display being coupled to the image reconstructor, and the display displaying the image of the object of interest (E) an X-ray controller, the X-ray controller being coupled to the cold cathode to provide control signals to control the emission of electrons from the plurality of emitters, wherein the electrons bombard the anode at a focal spot of the anode; and
wherein the X-ray controller adjusts the control signals for the plurality of emitters so as to cause the focal spot to wobble.
-
-
30. A medical imaging method comprising:
-
generating an X-ray beam at an X-ray source comprising a cathode having a curved emission surface, the cathode comprising a plurality of emitter cones and a thin film gate, the electron beam being emitted towards an anode so as to cause the anode to be bombarded with electrons, wherein the X-ray beam is produced in response to being bombarded by the electrons, wherein the electrons bombard the anode at a focal spot of the anode, wherein a size and shape of the focal spot is defined at least in part by a curvature of the curved emission surface, the generating step including emitting an electron beam from the cathode, wherein the X-ray source directs the X-ray beam through a patient, and wherein the emitting step further includes applying a first electric field between the thin film gate and the plurality of emitter cones, the first electric field causing the electrons to be emitted from the plurality of emitter cones, and applying a second electric field between the anode and the cathode, the second electric field causing the electrons to accelerate towards the anode;
detecting the X-ray beam after the X-ray beam passes through at least a portion of the patient;
constructing an image of a portion of the patient based on data collected during the detecting step; and
displaying the image of the portion of the patient. - View Dependent Claims (31)
monitoring an electrocardiograph signal produced in response to beating of the heart, the electrocardiograph signal being periodic with each cycle corresponding to cycles of the heart, and synchronizing activation and deactivation of the emitters to the electrocardiograph signal, such that the X-ray source is activated during the same portion of each of the cycles of the heart.
-
Specification