Gravity-fed toilet with quiet siphonic flush

We claim: 1. A toilet comprising: a bowl; a rim channel at an upper end up the bowl; a trapway including a trapway inlet connected at a lower end of the bowl and extending downstream from the bowl; and a bypass passage configured to connect the rim channel to the trapway. 2. The toilet of claim 1 , wherein the bypass passage is connected to the trapway at a timing position configured to break a siphon in the trapway. 3. The toilet of claim 2 , wherein the timing position causes the siphon to break at a predetermined time in a flush sequence. 4. The toilet of claim 3 , wherein an upstream end of the bypass passage is exposed to ambient air during the flush sequence before a downstream end of the bypass passage is exposed to ambient air during the flush sequence. 5. The toilet of claim 1 , wherein the bypass passage is configured to allow ambient air from outside the toilet to pass therethrough in only a single direction toward the trapway. 6. The toilet of claim 1 , wherein the bypass passage prevents noxious waste gas from exiting the trapway. 7. The toilet of claim 1 , wherein ambient air is introduced to the trapway through the bypass passage as a result of a pressure differential between the trapway and an environment surrounding the toilet. 8. The toilet of claim 1 , wherein water is introduced through the rim channel to the bowl and the trapway during a flush sequence. 9. The toilet of claim 1 , wherein the bypass passage extends at least partially upwardly from an upper surface of the toilet proximate to an inlet of the toilet. 10. The toilet of claim 1 , wherein an inlet of the bypass passage is fluidly connected to a first end of the trapway and an outlet of the bypass passage is fluidly connected to a second end of the trapway that is downstream from the first end. 11. A water and air passage network for toilet, the passage network comprising: a rim channel at an upper end up a bowl of the toilet; and a bypass passage configured to connect the rim channel to a trapway of the toilet. 12. The passage network of claim 11 , wherein the bypass passage is connected to the trapway at a timing position configured to break a siphon in the trapway. 13. The passage network of claim 12 , wherein the timing position causes the siphon to break at a predetermined time in a flush sequence. 14. The passage network of claim 13 , wherein an upstream end of the bypass passage is exposed to ambient air during the flush sequence before a downstream end of the bypass passage is exposed to ambient air during the flush sequence. 15. The passage network of claim 11 , wherein the bypass passage is configured to allow ambient air from outside the toilet to pass therethrough in only a single direction toward the trapway. 16. The passage network of claim 11 , wherein ambient air is introduced to the trapway through the bypass passage as a result of a pressure differential between the trapway and an environment surrounding the toilet. 17. The passage network of claim 11 , wherein water is introduced through the rim channel to the bowl and the trapway during a flush sequence. 18. A method for a flush sequence of a toilet, the method comprising: starting the flush sequence of the toilet; passing water from a rim channel into a bowl of the toilet; starting a siphon in a trapway of the toilet; and exposing the trapway air through a bypass passage connected the rim channel and connected to the trapway. 19. The method of claim 18 , further comprising: breaking the siphon in the trapway. 20. The method of claim 19 , wherein air is exposed to the trapway through the bypass passage prior to a water level falling below an upper end of a trapway inlet and the siphon is broken before the water level in the bowl falls below the upper end of the trapway inlet.