Abstract: Disclosed are vascular access devices, implantable dialysis grafts, and systems that include them useful in facilitating easy, accurate and reproducible cannulation or needle entry into an implantable device such as a hemodialysis graft, by localizing a portion of the implanted graft that contains one or more paramagnetic materials that operably define the physical boundaries of the target cannulation site/entry port by passage of an external magnetic detector wand over that portion of the patient's body into which the device has been implanted.

Abstract: Disclosed are vascular access devices, implantable dialysis grafts, and systems that include them useful in facilitating easy, accurate and reproducible cannulation or needle entry into an implantable device such as a hemodialysis graft, by localizing a portion of the implanted graft that contains one or more paramagnetic materials that operably define the physical boundaries of the target cannulation site/entry port by passage of an external magnetic detector wand over that portion of the patient's body into which the device has been implanted.

Abstract: Disclosed are vascular access devices, implantable dialysis grafts, and systems including them useful for improved access to implanted medical devices. Also disclosed are implantable hemodialysis vascular access graft devices that facilitate easy, accurate and reproducible cannulation or needle entry into the implanted device by magnetically-locating a portion of the graft that includes one or more paramagnetic materials operably defining the physical boundaries of the target cannulation site/entry port.

Abstract: A computer system (6,7) includes first and second I/O circuits (932, 934, 51, 97), first and second buses (904, 83) respectively coupled to the first and second I/O circuits (932, 934, 51, 97), a memory (106), a third bus (104) coupled to the memory (106), and first and second bus interface circuits (902, 6920) connected between the third bus (104) and the first and second buses (904, 83) respectively. A direct memory access (DMA) controller (910) is coupled to the first bus (904) and to the first bus interface circuit (902), and a serial communications circuit (7010, 6910, 7020) is connected between the DMA controller (910) and the second bus interface circuit (6920). As an example, in the present invention a single DMA controller may be used to provide DMA capability to both a notebook computer and a docking station, using an interface between the notebook computer and the docking station to transfer DMA related information between the DMA controller and a requesting device in the docking station.

Abstract: A computer system (6,7) includes first and second I/O circuits (932, 934), first and second buses (904, 83) respectively coupled to the first and second I/O circuits (932, 934), a memory (106), a third bus (104) coupled to the memory (106), and first and second bus interface circuits (902, 6920) connected between the third bus (104) and the first and second buses (904, 83) respectively. A direct memory access (DMA) controller (910) is coupled to the first bus (904) and to the first bus interface circuit (906), and a serial communications circuit (7010, 6910, 7020) is connected between the DMA controller (910) and the second bus interface circuit (6920). As an example, in the present invention a single DMA controller may be used to provide DMA capability to both a notebook computer and a docking station, using an interface between the notebook computer and the docking station to transfer DMA station. Other devices, systems and methods are also disclosed.

Abstract: A microprocessor device (102) includes a central processing unit (702) having a clock input, a clock generator (OSC, PLL) of clock pulses, a logic circuit (708) having an output to supply a clock control signal (SUSP), and a clock gate (3610) fed by the clock pulses and having a clock gate output (CPU.sub.-- CLK) coupled to the clock input of the central processing unit. The clock gate (3610) responds to the clock control signal (SUSP) to prevent said clock pulses (CPU.sub.-- CLK) from reaching the central processing unit within one clock cycle of a change in said clock control signal. Other devices, systems and methods are also disclosed.

Abstract: A computer system (6,7) includes first and second I/O circuits (932, 934), 51, 97 first and second buses (904, 83) respectively coupled to the first and second I/O circuits (932, 934), 51, 97 a memory (106), a third bus (104) coupled to the memory (106), and first and second bus interface circuits (902, 6920) connected between the third bus (104) and the first and second buses (904, 83) respectively. A direct memory access (DMA) controller (910) is coupled to the first bus (904) and to the first bus interface circuit (902), and a serial communications circuit (7010, 6910, 7020) is connected between the DMA controller (910) and the second bus interface circuit (6920). As an example, in the present invention a single DMA controller may be used to provide DMA capability to both a notebook computer and a docking station, using an related information between the DMA controller and a requesting device in the docking station. Other devices, systems and methods are also disclosed.

Abstract: A microprocessor device (102) includes a central processing unit (702) having a clock input, a clock generator (OSC, PLL) of clock pulses, a logic circuit (708) having an output to supply a clock control signal (SUSP), and a clock gate (3610) fed by the clock pulses and having a clock gate output (CPU.sub.-- CLK) coupled to the clock input of the central processing unit. The clock gate (3610) responds to the clock control signal (SUSP) to prevent said clock pulses (CPU.sub.-- CLK) from reaching the central processing unit within one clock cycle of a change in said clock control signal. Other devices, systems and methods are also disclosed.

Abstract: A microprocessor device (102) includes a central processing unit (702) having a clock input, a clock generator (OSC, PLL) of clock pulses, a logic circuit (708) having an output to supply a clock control signal (SUSP), and a clock gate (3610) fed by the clock pulses and having a clock gate output (CPU.sub.-- CLK) coupled to the clock input of the central processing unit. The clock gate (3610) responds to the clock control signal (SUSP) to prevent said clock pulses (CPU.sub.-- CLK) from reaching the central processing unit within one clock cycle of a change in said clock control signal. Other devices, systems and methods are also disclosed.