IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0265173
(1999-03-09)
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발명자
/ 주소 |
- Moster, Jeffrey A.
- Hensley, David W.
- Zerhusen, Robert M.
- Hamilton, Michael W.
- Hornbach, David W.
- Barbu, Olivier
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출원인 / 주소 |
|
대리인 / 주소 |
Bose McKinney & Evans LLP
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인용정보 |
피인용 횟수 :
5 인용 특허 :
12 |
초록
A waterproof cover is coupled to a surface of a housing coupled to a bed. The cover is configured to seal an opening formed in the housing against water penetration. The cover is also configured so that the sound waves are audible through the cover.
대표청구항
▼
A waterproof cover is coupled to a surface of a housing coupled to a bed. The cover is configured to seal an opening formed in the housing against water penetration. The cover is also configured so that the sound waves are audible through the cover. in the second predetermined plurality of frequenci
A waterproof cover is coupled to a surface of a housing coupled to a bed. The cover is configured to seal an opening formed in the housing against water penetration. The cover is also configured so that the sound waves are audible through the cover. in the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit substantially completely overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit, and a shape and period of said first predetermined spread spectrum profile is substantially identical to a shape and period of said second predetermined spread spectrum profile. 7. The method as recited in claim 1, further comprising: providing a synchronizing check circuit that generates a signal indicative as to whether or not said first and second spread spectrum clock generator circuits are correctly synchronized. 8. A multiple output spread spectrum clock generator circuit, comprising: a first spread spectrum clock generator circuit, and a second spread spectrum clock generator circuit; said first spread spectrum clock generator circuit outputting a first predetermined plurality of frequencies over a first predetermined time period, as according to a first predetermined spread spectrum profile; said second spread spectrum clock generator circuit outputting a second predetermined plurality of frequencies over a second predetermined time period, as according to a second predetermined spread spectrum profile, wherein the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit at least partially overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit; and a synchronization control logic circuit which controls in real time a frequency difference between the outputs of both said first and second spread spectrum clock generator circuits so that an overall increase in electromagnetic emissions due to a combination of said first and second spread spectrum clock generator circuits is less than 6 dB above the electromagnetic emissions due solely to said first spread spectrum clock generator circuit. 9. The multiple output spread spectrum clock generator circuit as recited in claim 8, wherein the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit substantially completely overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit, and wherein said overall increase in electromagnetic emissions is reduced by controlling a starting frequency of said second predetermined spread spectrum profile so that it exhibits a predetermined difference from a starting frequency of said first predetermined spread spectrum profile. 10. The multiple output spread spectrum clock generator circuit as recited in claim 8, wherein the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit substantially completely overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit, and wherein said overall increase in electromagnetic emissions is reduced by controlling a starting time of said second predetermined spread spectrum profile so that the starting time exhibits a predetermined difference from a starting time of said first predetermined spread spectrum profile, although the starting frequencies of both first and second predetermined spread spectrum profiles are substantially identical. 11. The multiple output spread spectrum clock generator circuit as recited in claim 9, wherein after both said first and second spread spectrum clock generator circuits are running, a phase difference between said first and second predetermined spread spectrum profiles results, and represents substantially one of 18% or 50% of the spread spectrum profile period. 12. The multiple output spread spectrum clock generator circuit as recited in claim 10, wherein after both said first and second spread spectrum clock generator circuits are running, said predetermined difference between the first and second starting times results in a phase difference between said first and second predetermined spread spectrum profiles, and said phase difference represents substantially one of 18% or 50% of the spread spectrum profile period. 13. The multiple output spread spectrum clock generator circuit as recited in claim 8, wherein the second predetermined plurality of frequencies of said second spectrum clock generator circuit substantially completely overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit, and a shape and period of said first predetermined spread spectrum profile is substantially identical to a shape and period of said second predetermined spread spectrum profile. 14. The multiple output spread spectrum clock generator circuit as recited in claim 8, wherein said synchronization control logic comprises one of: (a) a first decoder circuit that outputs a reset signal to said second spread spectrum clock generator circuit when it receives a predetermined binary number from an Address Counter of said first spread spectrum clock generator circuit; (b) a second decoder circuit that outputs a second signal when it receives a predetermined binary number from an Address Counter of said first spread spectrum clock generator circuit, a third decoder circuit that outputs a third signal when it receives a predetermined binary number from a Feedback Counter of said first spread spectrum clock generator circuit, and at least one logic gate that receives said second and third signals and outputs a reset signal to said second spread spectrum clock generator circuit; or (c) a flip-flop circuit that receives a rollover signal from an Address Counter of said first spread spectrum clock generator circuit and outputs a fourth signal, a counter circuit that receives a rollover signal from a Feedback Counter of said first spread spectrum clock generator circuit and outputs a fifth signal, and at least one logic gate that receives said fourth and fifth signals and outputs a reset signal to said second spread spectrum clock generator circuit. 15. The multiple output spread spectrum clock generator circuit as recited in claim 14, further comprising: a delay chain and multiplexer circuit that provides a fine control adjustment to said reset signal before it is directed to said second spread spectrum clock generator circuit. 16. The multiple output spread spectrum clock generator circuit as recited in claim 8, further comprising: a synchronizing check circuit that generates a "sync check" signal indicative as to whether or not said first and second spread spectrum clock generator circuits are correctly synchronized. 17. The multiple output spread spectrum clock generator circuit as recited in claim 16, wherein said synchronizing check circuit comprises: a first decoder circuit that outputs a first signal when it receives a predetermined binary number from an Address Counter of said first spread spectrum clock generator circuit; a second decoder circuit that outputs a second signal when it receives a predetermined binary number from a Feedback Counter of said first spread spectrum clock generator circuit; a third decoder circuit that outputs a third signal when it receives a predetermined binary number from an Address Counter of said second spread spectrum clock generator circuit; a fourth decoder circuit that outputs a fourth signal when it receives a predetermined binary number from a Feedback Counter of said second spread spectrum clock generator circuit; a "course sync" logic circuit that receives said first and third signals and outputs a fifth signal; a "fine sync" logic circuit that receives said second and fourth signals and outputs a sixth signal; and an output stage logic circuit that receives said fifth and sixth signals and outputs said "sync check" signal. 18. The multiple output spread spectrum clock generator circuit as recited in claim 8, wherein some of the circuit components are shared between both said first and s econd spread spectrum clock generator circuits. 19. The multiple output spread spectrum clock generator circuit as recited in claim 18, wherein said shared circuit components include: an input clock oscillator, a Base Register, a Start Register, a multiport RAM device, and an "ON" signal circuit; and further comprising: an initial address register that loads a binary number into an Address Counter of said second spread spectrum clock generator circuit. 20. The multiple output spread spectrum clock generator circuit as recited in claim 18, wherein said shared circuit components include: an input clock oscillator, a Base Register, a Start Register, an Address Counter, a multiport RAM device, and an "ON" signal circuit; and further comprising an address offset register and adder circuit that loads an offset address binary number into said multiport RAM device. 21. The multiple output spread spectrum clock generator circuit as recited in claim 8, further comprising: a third spread spectrum clock generator circuit which outputs a third predetermined plurality of frequencies over a third predetermined time period, as according to a third predetermined spread spectrum profile, wherein the third predetermined plurality of frequencies of said third spread spectrum clock generator circuit at least partially overlaps the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit; and wherein said synchronization control logic circuit is further configured to control in real time a frequency difference between the outputs of said first, second, and third spread spectrum clock generator circuits so that an overall increase in electromagnetic emissions due to a combination of said first, second, and third spread spectrum clock generator circuits is less than 9.5 dB above the electromagnetic emissions due solely to said first spread spectrum clock generator circuit. 22. A multiple output spread spectrum clock generator circuit, comprising: a first spread spectrum clock generator circuit, and a second spread spectrum clock generator circuit; said first spread spectrum clock generator circuit outputting a first predetermined plurality of frequencies over a first predetermined time period, as according to a first predetermined spread spectrum profile; said second spread spectrum clock generator circuit outputting a second predetermined plurality of frequencies over a second predetermined time period, as according to a second predetermined spread spectrum profile, wherein the second predetermined plurality of frequencies of said second spread spectrum clock generator circuit at least partially overlaps the first predetermined plurality of frequencies of said first spread spectrum clock generator circuit; and wherein said first spread spectrum clock generator circuit comprises a frequency synthesizer circuit, said second spread spectrum clock generator circuit comprises a programmable delay chain circuit and a tracking phase locked loop circuit, and said programmable delay chain circuit provides a temporal difference in real time between the outputs of both said first and second spread spectrum clock generator circuits so that an overall increase in electromagnetic emissions due to a combination of said first and second spread spectrum clock generator circuits is less than 6 dB above the electromagnetic emissions due solely to said first spread spectrum clock generator circuit.
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