Patent Number: 050705199
Section: claims

1. A selective equalization imaging system comprising: a source of penetrating radiation;  a control circuit causing the source to irradiate a patient with penetrating radiation and detecting radiation emerging from the patient to generate control signals identifying a lung field in the patient; and  an imaging circuit receiving said control signals and causing the source to scan the patient with penetrating radiation at exposure controlled in accordance with said control signals to vary with position over the patient but only outside the lung field identified by said control signals.  a source generating a beam of penetrating radiation scanning the object;  a modulator for locally modulating selected portions of the scanning beam; and  a control circuit controlling the modulator to cause the exposure which the beam delivers to the object to remain substantially constant over the selected field but to cause said exposure to vary elsewhere with selected local variations in the object.  generating a beam of penetrating radiation scanning the object; and  locally modulating portions of the scanning beam to cause the exposure which the beam of penetrating radiation delivers to the object to remain substantially constant over the selected field but to vary elsewhere with local variations in the object.  scanning an object position with a generally fan-shaped beam of penetrating radiation and moving, together with the scanning fan, attenuating elements which are arranged in at least one row extending in a direction transverse both to the scanning direction and to the propagation direction of the fan-shaped beam; and  moving the respective attenuating elements into the fan-shaped beam as a function of the spatial distribution of attenuating material at the object position but only outside a selected field of the object position.  generating a beam of penetrating radiation scanning an object;  locally modulating selected portions of the scanning beam;  controlling the modulating to cause the exposure which the beam delivers to the object to remain substantially constant over a selected field of the object but to vary elsewhere with selected local variations in the object.  generating a beam of penetrating radiation scanning the object; and  locally modulating portions of the scanning beam to cause the exposure which the beam delivers to the object to remain substantially constant or to vary in a first selected manner with variations in a selected property of the object over the selected field but to vary in a second selected manner elsewhere with local variations in a selected property of the object.  a source generating a beam of penetrating radiation scanning the object;  a modulator for selectively locally modulating selected portions of the scanning beam; and  a control circuit controlling the modulator in a first manner over said selected field and in a second manner outside the selected field, said second manner of control causing the exposure which the scanning beam delivers to the object to vary with selected local variations of a property of the object. 2. A system as in claim 1, in which said control circuit comprises a mapping circuit which is operative prior to said scanning to derive a two-dimensional map of a penetrating radiation response property of the patient and for deriving said control signals as a function of said map. 3. A system as in claim 2, in which the control circuit causes the source to scan the patient with a pre-scan beam of penetrating radiation at lower exposure than at the scan caused by the imaging circuit. 4. A system as in claim 3, in which said pre-scan beam is free of local modulation. 5. A system as in claim 1, in which said source comprises a collimator defining a fan-shaped beam of penetrating radiation and a modulator comprising modulator pins which are arranged along the fan-shaped beam and selectively move into the fan-shaped beam during said scanning in accordance with said control signals to attenuate the fan-shaped beam locally and thereby to control said exposure locally. 6. A system as in claim 5, in which said modulator pins have generally triangular sections in planes parallel to that of the fan-shaped beam and the areas of the sections defined by a given plane within the fan-shaped beam increase as the pins move further into the scanning fan-shaped beam. 7. A system as in claim 1, in which said control signals define a modulation function which determines the time and extent of the local modulation of the scanning beam, and wherein said modulation function is substantially constant over the lung field. 8. A selective equalization system for imaging an object having a selected field, comprising: 9. A system as in claim 8, including a pre-scan circuit which causes the source to carry out a pre-scan of the object with a beam of penetrating radiation and in response to the pre-scan generates a two-dimensional map of a property of the object related to transmission of the penetrating radiation and identifying said selected field, and wherein the control circuit is responsive to said map to control the modulator. 10. A selective equalization method of imaging an object having a selected field, comprising: 11. A method comprising the steps of: 12. A method comprising: 13. A method as in claim 12, including the step of pre-scanning the object with a pre-scan beam of penetrating radiation and in response generating a two-dimensional map of a property of the object related to transmission of the penetrating radiation and identifying said selected field, and wherein the controlling step is responsive to said map to control the modulating. 14. A method as in claim 13, in which the pre-scanning beam is free of local modulation. 15. A selective equalization method of imaging an object having a selected field, comprising: 16. A method as in claim 15, in which said selected property is related to the local transmission of said radiation through the object and including deriving a control signal related to the local transmission properties of the object and using said control signal to control the step of locally modulating portions of the scanning beam. 17. A method as in claim 16, in which said beam is thin in the vertical direction and wide in the horizontal direction and scans the object such that sectors of the beam move in respective vertical planes. 18. A method as in claim 15, in which the exposure is free of substantial variation over the selected field. 19. A selective equalization system for imaging an object having a selected field, comprising: 20. A selective equalization system as in claim 19, in which said first manner of control causes the exposure which the beam delivers to the object to remain substantially constant over the selected field.