IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0235338
(2002-09-05)
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발명자
/ 주소 |
- Gray, Matthew K.
- Peden, II, Jeffrey J.
- Chery, Yonald
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
338 인용 특허 :
7 |
초록
▼
A system and method for performing real-time position detection and motion tracking of mobile communications devices moving about in a defined space comprised of a plurality of locales is provided. A plurality of access points are disposed about the space to provide an interface between mobile devic
A system and method for performing real-time position detection and motion tracking of mobile communications devices moving about in a defined space comprised of a plurality of locales is provided. A plurality of access points are disposed about the space to provide an interface between mobile devices and a network having functionality and data available or accessible therefrom. Knowledge of adjacency of locales may be used to better determine the location of the mobile device as it transitions between locales and feedback may be provided to monitor the status and configuration of the access points.
대표청구항
▼
A system and method for performing real-time position detection and motion tracking of mobile communications devices moving about in a defined space comprised of a plurality of locales is provided. A plurality of access points are disposed about the space to provide an interface between mobile devic
A system and method for performing real-time position detection and motion tracking of mobile communications devices moving about in a defined space comprised of a plurality of locales is provided. A plurality of access points are disposed about the space to provide an interface between mobile devices and a network having functionality and data available or accessible therefrom. Knowledge of adjacency of locales may be used to better determine the location of the mobile device as it transitions between locales and feedback may be provided to monitor the status and configuration of the access points. e positive differential output; a second reset transistor connected between the reset voltage and the negative differential output, wherein gates of the first and second reset transistors are driven by the clock phase φ1. 10. The analog to digital converter of claim 9, wherein the first and second reset transistors are FET transistors. 11. The analog to digital converter of claim 7, further including sampling capacitors at the positive and negative differential outputs of the track-and-hold amplifier. 12. The analog to digital converter of claim 1, wherein a transfer function of the circuit for differential mode is HDM(φ1)=0, HDM(φ2)=1, and a transfer function for common mode is HCM(φ1)=1, HCM(φ2)=1. 13. The analog to digital converter of claim 1, wherein each of the amplifiers includes a plurality of amplifier stages, and wherein the circuit is coupled to an input of a first stage for each amplifier. 14. The analog to digital converter of claim 1, wherein each of the amplifiers includes a plurality of amplifier stages, and wherein the circuit is coupled to inputs of each stage. 15. The analog to digital converter of claim 1, wherein each of the amplifiers includes a plurality of amplifier stages, and wherein the circuit is coupled to inputs of alternating stages. 16. The analog to digital converter of claim 1, further including a sampling capacitor at each input of the amplifiers for sampling the output of the track-and-hold amplifier. 17. An analog to digital converter comprising: a track-and-hold amplifier tracking an input signal with its output signal during a clock phase φ1and holding a sampled value during a clock phase φ2; a first plurality of amplifiers each inputting a signal corresponding to the output signal and a reference voltage; a switching circuit that receives the signal corresponding to the output signal and has a differential mode transfer function of approximately 1 on the clock phase φ2and approximately 0 on the clock phase φ1; a second plurality of amplifiers inputting the reference voltages and the signal corresponding to the output signal through the switching circuit, the reference voltages selected based on outputs of the first plurality of amplifiers; and an encoder converting outputs of the first and second plurality of amplifiers to an N-bit digital signal representing the input signal. 18. The analog to digital converter of claim 17, wherein, for each amplifier of the second plurality of amplifiers, the circuit includes a plurality of transistors driven by either a supply voltage or the clock phase φ1. 19. The analog to digital converter of claim 18, wherein the transistors are FET transistors. 20. The analog to digital converter of claim 17, wherein, for each amplifier of the second plurality of amplifiers, the switching circuit includes two cross-coupled transistors, two signal inputs and two signal outputs, the two signal outputs differentially connected to differential inputs of each corresponding amplifier of the second plurality of amplifiers, the two signal inputs differentially connected to the output signal of the track-and-hold amplifier. 21. The analog to digital converter of claim 17, wherein the output signal includes positive and negative differential outputs of the track-and-hold amplifier, wherein the switching circuit includes first, second, third and fourth transistors, wherein sources of the first and second transistors are connected to a positive differential output of the track-and-hold amplifier through a first sampling capacitor, wherein sources of the third and fourth transistors are connected to a negative differential output of the track-and-hold amplifier through a second sampling capacitor, wherein drains of the first and third transistors are connected to a positive differe ntial input of the each amplifier of the second plurality of amplifiers, wherein drains of the second and fourth transistors are connected to a negative differential input of the each amplifier of the second plurality of amplifiers, and wherein gates of the second and third transistors are driven by the clock phase φ1. 22. The analog to digital converter of claim 21, wherein the transistors are FET transistors. 23. The analog to digital converter of claim 17, wherein the signal corresponding to the output signal includes positive and negative differential outputs of the track-and-hold amplifier, and further including a transistor connected between the positive and negative differential outputs of the track and hold amplifier, a gate of the transistor being driven by the clock phase φ1. 24. The analog to digital converter of claim 23, wherein the transistor is a FET transistor. 25. The analog to digital converter of claim 23, further including: a first reset transistor connected between a reset voltage and the positive differential output; a second reset transistor connected between the reset voltage and the negative differential output, wherein gates of the first and second reset transistors are driven by the clock phase φ1. 26. The analog to digital converter of claim 25, wherein the first and second reset transistors are FET transistors. 27. The analog to digital converter of claim 23, further including sampling capacitors at the positive and negative differential outputs of the track-and-hold amplifier. 28. The analog to digital converter of claim 17, wherein each amplifier of the second plurality of amplifiers includes a plurality of amplifier stages, and wherein the switching circuit is coupled to an input of a first stage for each amplifier of the second plurality of amplifiers. 29. The analog to digital converter of claim 17, wherein each amplifier of the second plurality of amplifiers includes a plurality of amplifier stages, and wherein the switching circuit is coupled to inputs of each stage. 30. The analog to digital converter of claim 17, wherein each amplifier of the second plurality of amplifiers includes a plurality of amplifier stages, and wherein the switching circuit is coupled to inputs of alternating stages. 31. The analog to digital converter of claim 17, wherein a transfer function of the switching circuit for common mode is HCM(φ2)=1, HCM(φ2)=1. 32. The analog to digital converter of claim 17, further including a sampling capacitor at each input of the first and second plurality of amplifiers for sampling the output of the track-and-hold amplifier. 33. An analog to digital converter comprising: a multi-phase clock; a track-and-hold amplifier tracking an input signal with its output signal during one phase of the multi-phase clock and holding a sampled value during another phase of the multi-phase clock; a first plurality of amplifiers each inputting a signal corresponding to the output signal and a reference voltage; switching means that receives the signal corresponding to the output signal and responsive to the multi-phase clock, the means substantially passing the signal corresponding to the output signal to a second plurality of amplifiers during the one phase and substantially rejecting the signal corresponding to the output signal during the another phase; the second plurality of amplifiers inputting, through the switching means, the reference voltages and the output signal, the reference voltages selected based on outputs of the first plurality of amplifiers; and an encoder converting outputs of the first and second plurality of amplifiers to an N-bit digital signal representing the input signal. 34. An analog to digital converter comprising: a plurality of amplifiers each sampling an input signal at an end of a clock phase φ1and each inputting a voltage referen
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