Abstract: Hypodermic needle 2 is to be introduced between the skin and the tissue adjacent to the skin. To separate the skin from the tissue, cartilage or bone below the skin and to prevent the tip 6 of the needle 2 from piercing the tissue below the skin this invention discloses providing the extremity 6 of the needle with a protrusion 4. To prevent damage to the living being in which the needle 2 is introduced the transition of the protrusion 4 to the needle is smooth in all directions. The protrusion 4 is provided on that side of the needle which will be adjacent to the tissue, cartilage or bone of the living being.

Abstract: A static antenna tuning and antenna voltage measurement circuit (40) includes antenna voltage conversion circuitry (44) for converting a voltage signal (42) to a measurement signal representative of transmitter/receiver antenna (16) operation. Voltage signal (42) arises from transmitter/receiver antenna (16) transmitting or receiving a recognition signal (S1, S2). Comparator circuitry (48, 50, 52) compares the measurement signal to a predetermined optimal transmitter/receiver antenna operation signal.

Abstract: A microprocessor of the superscalar pipelined type, having speculative execution capability, is disclosed. Speculative execution is under the control of a fetch unit having a branch target buffer and a return address stack, each having multiple entries. Each entry includes an address value corresponding to the destination of a branching instruction, and an associated register value, such as a stack pointer. Upon the execution of a subroutine call, the return address and current stack pointer value are stored in the return address stack, to allow for fetching and speculative execution of the sequential instructions following the call in the calling program. Any branching instruction, such as the call, return, or conditional branch, will have an entry included in the branch target buffer; upon fetch of the branch on later passes, speculative execution from the target address can begin using the stack pointer value stored speculatively in the branch target buffer in association with the target address.

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 transponder unit (10) includes an N cycle counter (30) and an M cycle counter (28). The N cycle counter (30) has a different cycle value than the M cycle counter (28). During the transmission of information from the transponder unit (10), the duration for data bits having a binary zero value is controlled by the N cycle counter (30). The duration of data bits having a binary one value is controlled by the M cycle counter (28). The use of different cycle values within the N cycle counter (30) and the M cycle counter (28) allows for the transmission of binary one and binary zero data bits having the same bit length despite different frequencies representing the binary one and binary zero bits respectively.

Abstract: A system and method in which a transponder (14) is operable to transmit an original user account balance to an interrogator (12), which in turn calculates a revised user account balance and transmits the revised user account balance to the transponder (14). In one embodiment of the invention, the transponder (14) is further operable to transmit a verification user account balance back to the interrogator (12), which then compares verification user account balance to the revised user account balance that was earlier calculated and stored in an interrogator memory.

Abstract: A master RF module (12), a slave RF module (20) without an internal oscillator, and additional circuitry (40) (52). A pick up coil (30) disposed perpendicular to the antenna (16) of the master RF module (12), is connected to the additional circuitry (40) (52). Transmission from the master RF module (12) is received by the pick up coil (30) and is filtered (42) (54), and amplified (44, 46) (64, 78) by the additional circuitry (40) (52). The amplified signal is used as an oscillator input (22) to the slave RF module (20) and is also converted into a square wave monoflop signal by square wave converter (48) (98) for enabling the transmitter control (24) of the slave RF module (20).

Abstract: Transponder signal collision avoidance system incudes a reader and wireless HDX or FDX type transponders (A, B) are disclosed, interrogated by the reader (R) by alternately powering and then reading through cycles corresponding to a number of possible transponders in the interrogation field. The cycles, which include reader power pulses, signify addresses of respective possible transponders, whether in or out of the field. The transponders for this purpose count reader power pulses by end-of-burst detection, increasing a stored count value with each reader power pulse. The transponder responds to the reader by transmission if and only if a stored count value in a read cycle matches a respective transponder address, preventing the transponders from transmitting telegrams interfering with each other.

Abstract: A method and apparatus for sensing corrosion are provided in which an interrogation unit (14) transmits interrogation pulses and receives responses. A plurality of corrosion sensors (12) are disposed in the structure to be monitored (10), each of the sensors (12) generating an output. A plurality of responders (16) are powered from the interrogation pulses, one each of the responders (16) associated with one each of the sensors (12). The responders (16) are operable to transmit responses to the interrogation pulses based on the corrosion sensors' (12) output.

Abstract: Apparatus for introducing a transponder in a living being wherein the transponder itself is outfitted with a sharpened member attached to the injection end of a transponder. The sharpened member comes in contact with the skin before the transponder thereby creating an opening in the skin such that the transponder can be blunt edged and move into the opening easily. The sharpened member is preferably constructed of a bio-compatible, preferably biodegradable material which may carry medication additionally.

Abstract: An integrated circuit includes a single chip (102) that has a microprocessor (702), a memory controller unit (718), an internal bus (714) connecting the microprocessor (702) and the memory controller unit (718), and an external bus to internal bus interface circuit (716). The microprocessor (102) occupies a substantially rectangular region on a substrate (802). The memory controller unit (718) occupies a first strip along one side of the microprocessor unit (702) accessible via the bond pads broadside to the first strip. Other circuits, systems, and methods are disclosed.

Abstract: An electronic system (6) has a power management logic circuit (920). A first power supply connector (1902) is electrically coupled to the power management logic circuit (920) and a second power supply connector (1904) is also electrically coupled to the power management logic circuit (920). The power management logic circuit (920) has a first logic section (920A) connected to the first power supply connector (1902), and the first logic section (920A) has a suspend output (SUSPEND#). A second logic section (920B) is connected to the second power supply connector (1904) for operation independent of the first logic section (920A) when power is available at the second power supply connector (1904, . . . RTCPWR) and suspended at the first power supply connector (1902, VCC).Other devices, systems and methods are also disclosed.

Abstract: The invention is an improved method and apparatus for synchronizing wireless communications utilizing a master source (10) for a transmitting a synchronizing pulse to multiple reader modules (20 and 28) each of which has an internal crystal oscillator (22 and 30). The synchronizing pulse periodically resets the interrogation cycle, the power burst and receive cycle, for all of the reader modules (20 and 28). Between pulses, the internal crystal oscillator (22 and 30) is used to run interrogation cycles, and thus functions as a "flywheel" to absorb fluctuations in the synchronizing pulse such as when a particular synchronizing pulse is missed.

Abstract: A key (10) is provided that includes a key body (12) having a forked end. The forked end comprises a first tine (14) and a second tine (16). A transponder (20) is disposed between the first tine (14) and the second tine (16). The transponder (20) is operable to generate signals. An air coil antenna (18) is coupled to the key body (12) proximate the forked end and is electrically coupled to the transponder (20). The air coil antenna (18) is operable to transmit signals generated by the transponder (20).

Abstract: A thin and flat integrated circuit assembly (10, 40) may be achieved by using a thin carrier (20) with shallow cavities (22, 24) for holding the integrated circuits (16) and/or discrete circuit components (14). The integrated circuits (16) and/or circuit components (14) may be friction fitted in the cavities (22, 24) or they may be secured therein by the use of adhesives and/or solder. Electrical connection between the integrated circuits (16) and circuit components (14) may be done with wire bonding, ribbon bonding, tape-automated bonding, lead frames, flip chip bonding, and/or conductive gluing of leads. The circuit assembly may then be accommodated into a credit card-sized packaging with standard dimensions set by the International Standards Organization.

Abstract: A demodulator 5 is provided which may be constructed at low cost, can be integrated into current systems, and needs no external adjustments. The FSK demodulator 5 comprises a circuit 23 for generating an intermediate signal 101 as a function of high frequency intervals and low frequency intervals of an input FSK signal 100 and a circuit 24 for generating a demodulated output signal 102 as a function of the intermediate signal 101. According to one possible embodiment of the invention, an FSK signal 100 is demodulated by sending an FSK signal 100 through at least two retriggerable monostable multivibrators 23 and 24 each connected to an RC circuit 47 and 48 used to identify the high frequency and low frequency intervals of the input signal. The RC circuit components can be changed to accommodate FSK signals which use different frequencies for high and low input.

Abstract: A method of identifying an object and determining in which of at least two areas the object is located is disclosed. The method includes the steps of: focusing a first directional antenna (18) on a first area (28a), focusing a second directional antenna on a second area (28b), transmitting a first field strength pulse (44) from said first directional antenna (18), transmitting a second field strength pulse (46) from said second directional antenna (18), and comparing in a transponder (14) the first field strength pulse (44) to the second field strength pulse (46) to determine in which of the two areas (28a,28b) the transponder (14) is located. Other devices, systems and methods are also disclosed.

Abstract: A method and system is provided for communicating permanent or semi-permanent information to a transponder (14) from an interrogator (12), preferably operated by a toll agency or other authorized entity. This permanent or semi-permanent information is communicated by means of special instructions valid only during a special mode or maintenance mode which is entered by transmitting a special access code to the transponder (14) from the authorized interrogator (12). The transponder (14) will preferably acknowledge to the authorized interrogator (12) that it is, in fact, operating in the maintenance mode so the interrogator (12) can transmit the special instructions in confidence.

Abstract: A method of identifying an object and determining in which of at least two areas the object is located is disclosed. The method includes the steps of: focusing a first directional antenna (18) on a first area (28a), focusing a second directional antenna on a second area (28b), transmitting a first field strength pulse (44) from said first directional antenna (18), transmitting a second field strength pulse (46) from said second directional antenna (18), and comparing in a transponder (14) the first field strength pulse (44) to the second field strength pulse (46) to determine in which of the two areas (28a,28b) the transponder (14) is located. Other devices, systems and methods are also disclosed.

Abstract: A method is described with the aid of which messages can be transmitted from batteryless transponders to interrogation devices. The interrogation devices are equipped with a receiving section and a transmitting section and as a request to transmit the message stored therein as reaction to an interrogation command rendered effective in the interrogation device said devices transmit an HF interrogation pulse with predetermined carrier frequency and predetermined carrier duration. In the transponder this HF interrogation pulse is utilized to generate a supply voltage. Each interrogation device checks as reaction to an interrogation command whether its receiving section (14) is receiving a signal with the carrier frequency.