Abstract:
A video imaging system that minimizes the effect of EMI on the image data, provides a small, lightweight easy to use camera head, permitting interchangeable use of a variety of intelligent camera heads with a single camera control unit, and allows the utilization of new camera heads with new functions as they become available without having to replace the existing CCU.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present application is a continuation of and claims priority from U.S. patent application Ser. No. 10/033,316, filed Dec. 28, 2001, now U.S. Pat. No. 7,471,310, the content of which is incorporated herein by reference. 
    
    
     FIELD OF THE INVENTION 
     The invention relates to a camera head having components permitting its interchangeable use with a variety of camera control units. 
     BACKGROUND OF THE INVENTION 
     The field of video endoscopy, to which the present invention generally relates, includes medical diagnostic and therapeutic disciplines that utilize endoscopes to penetrate and view otherwise inaccessible body cavities utilizing minimally invasive surgical procedures. Coupling of video imaging cameras (incorporating solid-state imagers) to endoscopes, for image reproduction, has become standard within the field. Endoscopic video cameras (hereinafter referred to as “camera heads”), are most advantageously small and lightweight for ease of use by medical personnel, and typically incorporate either single or multiple solid-state imagers. Some special purpose endoscopes have integrated (built-in) solid-state imagers, which do not facilitate direct viewing of internal body cavities by medical personnel without an accompanying video imaging system and display. To achieve the desired size and weight, camera head and/or integrated endoscope-camera assembly electronics are typically separated physically from the majority of circuitry required to process and output high-quality, color video images. 
     Typically, endoscopic camera heads are sterilized prior to each use, because camera heads and endoscopes enter the “sterile field” during a surgical procedure. Camera control units (“CCUs”), which contain the majority of the electronic circuitry required to process video images, are typically not sterilized, and are placed on or in carts, or permanently wall-mounted. In known video imaging systems, interconnection is achieved by means of a cable, with usually one cable end permanently fixed to the camera head, while the other cable end is detachably connected to the CCU using a connector. Similar to the camera head itself, it is advantageous that cables be small in diameter and lightweight, but rugged enough to withstand repeated sterilization, accidental gurney wheel “run-over,” and the like. 
     Known video imaging systems typically include at least one camera head with a fixed cable, and often either a CCU having various input connections or different CCUs for each camera type. The input connections to the CCU are keyed so that specific camera heads can only be connected to a specific one of various inputs or to a particular CCU that corresponds to that particular camera head specifications. Timing signals, video system function command signals, and camera head supply voltages are all generated in the CCU for transmission to the camera head. The advantage to this camera head arrangement is small size, lightweight and easy maneuverability. Disadvantageously, only camera heads requiring timing signals matched to the CCUs timing generator may be utilized with this arrangement. Therefore, new or differing camera heads utilizing different timing signals cannot be utilized. 
     Another disadvantage of known video imaging systems is that the various camera heads have differing cable structures based upon the camera head parameters. Each camera head typically is matched to its own specifically configured cable. 
     Existing interconnections between camera heads and CCUs typically comprise dedicated parallel wires to provide greater data carrying capacity. It is meant by “dedicated parallel wires” that each specific signal is transmitted by means of an individual wire, either single for power and control signals or shielded coax for image data, between a camera head and CCU. However, a disadvantage of providing dedicated parallel wires is that typically twenty to thirty separate lines are required to control, energize and receive image data from camera heads, with most signal lines requiring a dedicated connector pin. The more lines required, the greater the diameter, size and corresponding weight of the cable bundle. The larger this bundle becomes, the more likely it is to interfere with medical personnel&#39;s use of the video imaging system. Moreover, utilizing dedicated parallel wire type cabling is undesired when additional functionality is required and added to either the camera head or CCU. To accommodate this new functionality, additional wiring must be incorporated in the cable bundle, requiring equipment redesign and subsequent purchase by customers. Also, as video imaging systems develop, CCUs are becoming programmable for compatibility with various types of camera heads, are adding new control features and are processing different types of video signals. 
     Another aspect of video imaging systems is that undesired image “noise” can be encountered, due to stray electromagnetic signals being induced upon the wires of the cable bundle (commonly referred to as electromagnetic interference, “EMI”), and from signal “cross-talk” within the cable itself. Known video imaging systems utilize analog signals for transmitting video and other signals to or from camera heads and CCUs. These analog signals, especially image data, are very susceptible to EMI from surgical electro-cautery equipment and the like. The use of EMI shielding is prohibitive due to the added cost and subsequent cable size and weight increase. Moreover, the desired endoscopic camera head cable length itself (typically 10 feet or more) tends to induce noise as analog signals are propagated down its length. 
     Additionally, solid-state imaging devices of higher resolution are becoming available and commercially feasible for use in video imaging systems. As imagers increase in sophistication, greater amounts of image data must be transmitted by means of the interconnection cable between camera heads and CCUs, and thus higher speed data transmission means must be utilized. 
     What is desired, therefore, is to provide a video imaging system where interconnection of camera heads is not limited to only those camera heads compatible with the timing signals generated in the CCU. Rather, a video imaging system is desired that enables the CCU to process image data and receive control signals from, and to issue command signals to, many types of camera heads, each having differing timing signal requirements. 
     It is further desired to provide a video imaging system that is resistant to both internal and external electromagnetic interference that does not require utilization of heavy shielding. This advantageously will enable the use of a small diameter, lightweight cable. 
     It is further desired to provide a video imaging system enabling camera heads and CCUs to take advantage of new features and functions without requiring redesign and/or replacement of the system. Such a configuration would provide the ability to accommodate future video camera system improvements and adaptations as current technology limitations are overcome, without obsolescing initial customer investments in CCUs. 
     It is further desired to provide a video imaging system that enables the use of a single pair of wires for transmission of control, command and image data transmission from and to the camera head and the camera control unit. 
     SUMMARY OF THE INVENTION 
     These and other objects of the invention are achieved in one advantageous embodiment by providing a video imaging system comprising: a camera control unit for processing a digital image signal; a cable, connected to said camera control unit, for transmitting the digital image signal to said camera control unit; and a camera head, connected to said cable, for providing the digital image signal, said camera head including: an imager, for generating an analog image signal; a timing generator, for actuating said imager; a converter, for converting the analog image signal into the digital image signal; and a serializer, for serializing the digital image signal for transmission over said cable. 
     In another advantageous embodiment a video imaging system is provided comprising: a camera control unit for processing an image signal; a cable, connected to said camera control unit, for transmitting the image signal to said camera control unit; and a camera head, connected to said cable, for providing the image signal, said camera head including: an imager, for generating the image signal; and a timing generator, for actuating said imager. 
     In a further advantageous embodiment a video imaging system is provided comprising: a camera control unit for processing a digital image signal; a cable, connected to said camera control unit, for transmitting the digital image signal to said camera control unit; and a camera head, connected to said cable, for providing the digital image signal, said camera head including: an imager, for generating an analog image signal; and a converter, for converting the analog image signal into the digital image signal. 
     In yet another advantageous embodiment a video imaging system is provided comprising: a camera control unit for processing an image signal; a cable, connected to said camera control unit, for transmitting the image signal to said camera control unit; and a camera head, connected to said cable, for providing the image signal, said camera head including: an imager, for generating an image signal; and a serializer, for serializing the image signal for transmission over said cable. 
     In still another advantageous embodiment a video imaging system is provided comprising: a camera control unit for processing an image signal, a cable, connected to said camera control unit, for transmitting the image signal to said camera control unit, and a camera head, connected to said cable, for providing the image signal, said camera head including: an imager, for generating the image signal; and a processor. 
     In a further advantageous embodiment a video imaging system is provided having a small diameter, lightweight, universal cable configuration, utilizing low-voltage differential signals (“LVDS”). Although various other signal methods may be used, LVDS based architecture is preferred due to its low power consumption, high-speed data transfer rate, two-wire unidirectional connectivity, and high resistance to internal (cross-talk) and external electromagnetic interference. The cable architecture is designed to reliably transmit and receive data from different camera heads to CCUs, as well as accommodate the differing technical requirements of different camera heads. 
     The cable has also been provided to accommodate the use of programmable CCUs. For instance, a camera head is connected by means of the universal cable to a programmable CCU. Software executing on the programmable CCU verifies connection to the camera head and retrieves camera head information relating specifically to that camera head. Camera head information may include command and control data comprising: software programs, operating information, timing signal data, camera head identification information, camera use information and the like. Control signals include any signal transmitted from the camera head except image data, such as timing signals generated by the timing generator, and signals generated by the processor. Command signals include any signal transmitted from the camera control unit to the camera head. 
     The architecture of the universal cable also greatly increases the data carrying capacity of the cable connection between the various CCUs and the varying camera heads. This need for increased data carrying capacity can be achieved by means of data multiplexing, while still maintaining the desired small diameter, and weight of a single cable. What is meant by “data multiplexing” is that any single signal path can be utilized for transmitting multiple data streams on a time-sharing basis. The new cable architecture will also allow for a greater cable length while not sacrificing data carrying capacity or inducing signal noise. 
     In a further advantageous embodiment a video imaging system is provided where the digital camera head comprises at least one processing device used to receive parallel digital video data and compress the data into a digital serial data stream for reception by at least one digital serial driver; and to receive digital serial data from at least one digital serial receiver. The programming flexibility realized using at least one processing device (such as, but not limited to, field programmable gate arrays, computer programmable logic devices, digital signal processors, and microprocessors) provides the necessary speed, precision, and adaptability desired for endoscopic video camera applications. Moreover, camera head physical size, production costs, and power consumption considerations are further mitigated by using a processor based video data compression and conversion configuration, instead of using discrete multiplexing devices. Additionally, as imager technologies improve, the invention can be easily adapted, by means of programming revision, to further exploit those improvements. 
     The invention and its particular features and advantages will become more apparent from the following detailed description considered with reference to the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram illustrating an embodiment of the video imaging system—including the camera head, universal cable and camera control unit. 
         FIG. 2  is a block diagram illustrating an embodiment of the video imaging system—including the camera head, universal cable and camera control unit. 
         FIG. 3  is a block diagram illustrating an embodiment of the video imaging system—including the camera head, universal cable and camera control unit. 
         FIG. 4  is a block diagram illustrating an embodiment of the video imaging system—including the camera head, universal cable and camera control unit. 
         FIG. 5  is a block diagram illustrating an embodiment of the video imaging system—including the camera head, universal cable and camera control unit. 
         FIG. 6  is a block diagram illustrating an embodiment of the endoscopic system, the universal cable interconnecting a single imager camera head with a CCU. 
         FIG. 7  is a block diagram illustrating an embodiment of the endoscopic system, the universal cable interconnecting a multiple imager camera head with a CCU. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1  illustrates an advantageous embodiment of the video imaging system  100 . A camera head  105  is provided having an imager  115  for receiving photonic energy  110  reflected off a viewed object (not shown). The imager  115  utilizes timing signals generated in timing generator  125  to develop output analog image data corresponding to the received photonic energy  110 . The imager  115  converts the received photonic energy  110  to output analog image data received by analog-to-digital converter  120 . The analog-to-digital converter  120  in turn converts the received analog image data to digital image data. The digital image data is then fed into multiplexer  130 . The timing generator  125  also provides an input to multiplexer  130 . A processor  135 , having access to a memory device  140  is also located in the camera head  105 . The processor  135  may send camera information stored in memory device  140  to multiplexer  130 . The multiplexer  130 , multiplexes the various received input signals, generating a multiplexed digital signal. The output of multiplexer  130  is connected to serializer  145 , also located in camera head  105 . The output of serializer  145  is then connected to digital serial driver  150 . The output of digital serial driver  150  is coupled to camera control unit  160  via coupling element  155 . Camera control unit  160  processes the received signal via processor  165 . The processor  165  utilizes timing signals generated in timing generator  125  to process the received image data in order to generate video output  170 . 
       FIG. 2  illustrates an advantageous embodiment of the video imaging system  200 . A camera head  205  is provided having an imager  215  for receiving photonic energy  210  reflected off a viewed object (not shown). The imager  215 , located in camera head  205 , utilizes timing signals generated in timing generator  220 , also located in camera head  205 , to develop output image data corresponding to the received photonic energy  210 . 
     The output of imager  215  is coupled to processor  245 , located in camera control unit  240 , via coupling element  225 . In addition, an output from timing generator  220  is coupled to processor  245 , located in camera control unit  240 , via coupling element  230 . Processor  245  utilizes timing signals generated in timing generator  220  to process the received image data in order to generate video output  250 . 
       FIG. 3  illustrates an advantageous embodiment of the video imaging system  300 . A camera head  305  is provided having an imager  315  for receiving photonic energy  310  reflected off a viewed object (not shown). The imager  315  develops output analog image data corresponding to the received photonic energy  310 . The imager  315  converts the received photonic energy  310  to output analog image data received by analog-to-digital converter  320 . The analog-to-digital converter  320  in turn converts the received analog image data to digital image data. The output of analog-to-digital converter  320  is then coupled to camera control unit  330  via coupling element  325 . Camera control unit  330  processes the received digital image data to generate video output  335 . 
       FIG. 4  illustrates an advantageous embodiment of the video imaging system  400 . A camera head  405  is provided having an imager  415  for receiving photonic energy  410  reflected off a viewed object (not shown). The imager  415  develops output image data corresponding to the received photonic energy  410 . The imager  415  converts the received photonic energy  410  to output image data received by multiplexer  420 , also located in camera head  405 . A memory device  425 , located in the camera head  405 , is also coupled to multiplexer  420 . The multiplexer  420 , multiplexes the various received input signals, generating a multiplexed signal. The output of multiplexer  420  is coupled to camera control unit  435  via coupling element  430 . Camera control unit  435  processes the received signal to generate video output  440 . 
       FIG. 5  illustrates an advantageous embodiment of the video imaging system  500 . A camera head  505  is provided having an imager  515  for receiving photonic energy  510  reflected off a viewed object (not shown). The imager  515  develops output image data corresponding to the received photonic energy  510 . The imager  515  converts the received photonic energy  510  to output image data received by serializer  520 , also located in camera head  505 . The output of serializer  520  is coupled to camera control unit  530  via coupling element  525 . Camera control unit  530  processes the received signal to generate video output  535 . 
       FIG. 6  illustrates an advantageous embodiment the video imaging system  600 , as applied to a single solid-state imager camera head  605 , and CCU  610 . The video imaging system  600  includes a universal cable  615 , which connects camera head  605  to CCU  610 . Solid-state imager  620  receives photonic energy  625  reflected off a viewed object (not shown). Imager  620 , being a charge coupled device (“CCD”), charge injection device (“CID”), or complementary metal oxide semiconductor (“CMOS”) device, or the like, converts the photonic energy into a representative analog voltage, which is received by correlated double sampler (“CDS”)  630 . Amplifier  635  receives the analog output of CDS  630 . The output of amplifier  635  is analog image data varying in accordance with the output of imager  620  in reference to the gain level setting of amplifier  635 . The analog image data output from amplifier  635  is received by analog-to-digital (“A/D”) converter  640 , which outputs a stream of digital image data (by means of a plurality of parallel lines) corresponding to the “varying” analog image data output by amplifier  635 . CDS  630 , amplifier  635 , and A/D converter  640  can be discrete devices, but it is preferred that all be integrated into a single device, and more preferred to utilize a device such as, but not limited to, Exar, part no., XRD98L59 Image Digitizer, or National Semiconductor, part no. LM98501 or LM98503 Camera Signal Processors. Such integrated devices are in common use within the video camera head field. 
     Processor  645  receives the parallel digital image data output by A/D converter  640 , to compress the data into a digital serial data stream for reception by digital serial driver  650 . Processor  645  can be, but is not limited to, a processor type such as field programmable gate arrays, computer programmable logic devices, digital signal processors, and microprocessors. Processor  645  outputs digital serial image data, which is received by digital serial driver  650 . Although various other digital serial drivers may be used, a low-voltage differential signal driver is preferred, for reasons previously detailed, and more preferred is to utilize a device such as, but not limited to, Texas Instruments, part no. SN65LVDS1 High-Speed Differential Driver. The output of digital serial driver  650  is connected to first connector  655 . 
     Universal cable  615  is terminated at a second end with a second connector  660 . To provide interconnection between camera head  605  and CCU  610  via universal cable  615 , the second connector  660  is secured to first connector  655 . Further, a third connector  665  is provided for securing to a fourth connector  670 . The input to digital serial receiver  675  is connected to a fourth connector  670 . Although various other digital serial receivers may be used (necessarily being compatible with digital serial driver  650 ), a low voltage differential signal receiver is preferred, for reasons previously detailed, and more preferred to utilize a device such as, but not limited to, Texas Instruments, part no. SN65LVDS2 High-Speed Differential Receiver. The output of digital serial receiver  675  is connected to image processing circuitry  680 , for eventual output of image data  685 . Image data  685  for display on a video monitor or other video equipment (not shown), as is common within the field. 
     A further function provided in this advantageous embodiment is the ability to send control and/or command signals to, and write information to the camera head  605  via processor  645 . The input to digital serial driver  690  is connected to image processing circuitry  680  and the output of digital serial driver  690  is connected to the fourth connector  670 . In this manner, information and data may be transmitted to the camera head  605  via the universal cable  615 . In the camera head  605 , the input to digital serial receiver  695  is connected to the first connector  655  for receiving the transmitted information and/or data from digital serial driver  690 . In addition, the output to digital serial receiver  695  is connected to processor  645  to effect control and/or command signals and to store data. 
       FIG. 7  illustrates the video imaging system  700 , as applied to a multiple solid-state imager camera head  705 , and CCU  710 . The video imaging system  700  includes, a universal cable  715 , which connects camera head  705  to CCU  710 . Common within the field, multiple imagers are affixed to a prism assembly (not shown), which splits received photonic energy ( 725   a ,  725   b , and  725   c ) into three separate wavelength bands (red, blue and green, in the case of visible light camera systems), which are then detected by the solid-state imagers ( 720   a ,  720   b , and  720   c ). This configuration produces higher resolution images than a single imager configuration. Solid-state imagers ( 720   a ,  720   b , and  720   c ) receive photonic energy ( 725   a ,  725   b , and  725   c ) from a prism assembly (not shown). Imagers ( 720   a ,  720   b , and  720   c ) being a CCD, CID, or CMOS device, or the like, convert the photonic energy ( 725   a ,  725   b , and  725   c ) into representative analog voltages, which are received by CDS ( 730   a ,  730   b , and  730   c ). Analog outputs of CDS ( 730   a ,  730   b , and  730   c ) are received by amplifiers ( 735   a ,  735   b , and  735   c ). The output analog image data of amplifiers ( 735   a ,  735   b , and  735   c ) vary in accordance with the output of imagers ( 720   a ,  720   b , and  720   c ) in reference to the gain level setting of amplifiers ( 735   a ,  735   b , and  735   c ). The analog image data output from amplifiers ( 735   a ,  735   b , and  735   c ) is received by A/D converters ( 740   a ,  740   b , and  740   c ), which each output a stream of digital image data (by means of a plurality of parallel lines) corresponding to the “varying” analog image data outputs by amplifiers ( 735   a ,  735   b , and  735   c ). CDS  730   a , amplifier  735   a  and A/D  740   a  (as well as CDS  730   b  and  730   c , amplifiers  735   b  and  735   c , and A/Ds  740   b  and  740   c ) can be discrete devices, but it is preferred that all be integrated into a single device, and more preferred to utilize a device such as, but not limited to, Exar, part no., XRD98L59 Image Digitizer, or National Semiconductor, part no. LM98501 or LM98503 Camera Signal Processors. Such integrated devices are in common use within the video camera field. 
     Processor  745  receives the parallel digital image data, to compress the data into a digital serial data stream for reception by digital serial drivers ( 750   a ,  750   b , and  750   c ). Processor  745  can be, but is not limited to, a processor type such as field programmable gate arrays, computer programmable logic devices, digital signal processors and microprocessors. Processor  745  outputs digital serial image data, which is received by digital serial drivers ( 750   a ,  750   b , and  750   c ). Although various other digital serial drivers may be used, low-voltage differential signal drivers are preferred, for reasons previously detailed, and more preferred is to utilize a device such as, but not limited to, Texas Instruments, part no. SN65LVDS1 High-Speed Differential Driver. The outputs of digital serial drivers ( 750   a ,  750   b , and  750   c ) are connected to second connector  755 . 
     Universal cable  715  is terminated with a first connector  760  at the first end. To provide interconnection between camera head  705  and CCU  710  via universal cable  715 , first connector  760  is secured to second connector  755 , and a third connector  765 , which is terminated on the second end of cable  715 , is secured to fourth connector  770 . Digital serial receivers ( 775   a ,  775   b , and  775   c ) inputs are connected to fourth connector  770 . Although various other digital serial receivers may be used (necessarily being compatible with digital serial drivers ( 750   a ,  750   b , and  750   c ), low voltage differential signal receivers are preferred, for reasons previously detailed, and more preferred is to utilize a device such as, but not limited to, Texas Instruments, part no. SN65LVDS2 High-Speed Differential Receiver. The outputs of digital serial receiver ( 775   a ,  775   b , and  775   c ) are attached to video processing circuitry  780 , for eventual output of video signal  785 . Video signal  785  is intended to be displayed on a video monitor or other video equipment (not shown), as is common within the field. 
     A further function provided in this advantageous embodiment is the ability to send control and/or command signals to, and write information to the camera head  705  via processor  745 . The input to digital serial drivers ( 790   a ,  790   b ,  790   c ) is connected to image processing circuitry  780  and the output of digital serial drivers ( 790   a ,  790   b ,  790   c ) is connected to fourth connector  770 . In this manner, information and data may be transmitted to the camera head  705  via the universal cable  715 . In camera head  705 , the input to digital serial receivers ( 795   a ,  795   b ,  795   c ) is connected to second connector  755  for receiving the transmitted information and/or data from digital serial drivers ( 790   a ,  790   b ,  790   c ). In addition, the output to digital serial receivers ( 795   a ,  795   b ,  795   c ) is connected to processor  745  to effect control and/or command signals and to store data. 
     The video imaging systems  600  ( 700 ) in  FIGS. 6 and 7  have been designed to accommodate anticipated future data carrying requirements. Endoscope systems will, most likely, continue to become more flexible. For instance, CCUs are becoming programmable for compatibility with various types of cameras, are adding new control features, and are processing differing image signals. 
     In view of this, the video imaging systems  600  ( 700 ) have been designed to effectively transmit data between different camera heads and CCUs in order to utilize programmable CCUs. As depicted in  FIGS. 6 and 7 , digital serial drivers  650  ( 750   a ,  750   b  and  750   c ) and digital serial receivers  675  ( 775   a ,  775   b  and  775   c ) provide this data capability. In like manner to digital serial drivers/receivers  650  ( 750   a ,  750   b  and  750   c ) and  675  ( 775   a ,  775   b  and  775   c ), various digital serial drivers and receivers may be utilized, but a low-voltage differential signal driver and receiver are preferred, for reasons previously detailed, and more preferred to utilize devices such as, but not limited to, Texas Instruments, part no. SN65LVDS1 High-Speed Differential Driver and part no. SN65LVDS2 High-Speed Differential Receiver. 
     As depicted in  FIG. 7 , digital serial drivers ( 750   a ,  750   b  and  750   c ; and  690   a ,  690   b  and  690   c ), and digital serial receivers ( 775   a ,  775   b  and  775   c ;  695   a ,  695   b  and  695   c ) are provided for expanded data and control capabilities as future video imaging system improvements are realized. 
     As depicted in  FIGS. 6 and 7 , to eliminate the need for a different cable type for each camera head configuration, the universal cable  615  ( 715 ) is designed to be compatible with a variety of camera heads. A generic universal cable  615  ( 715 ) would be used for both multiple and single image sensor cameras  605  ( 705 ). This would be accomplished by providing a universal cable  615  ( 715 ) with sufficient data carrying capacity to accommodate a multi-imager digital camera, as depicted in  FIG. 7 . If the same cable were utilized with a single imager digital camera, as depicted in  FIG. 6 , then the signal paths not being utilized would not be connected within the camera. Therefore, a single generic universal cable  615  ( 715 ) is usable with a variety of camera heads, eliminating the need to stock a specific cable for differing video imaging system types. 
     Although the invention has been described with reference to a particular arrangement of parts, features and the like, these are not intended to exhaust all possible arrangements or features, and indeed many other modifications and variations will be ascertainable to those of skill in the art.