Acoustic knock detection in dual-fuel engines

What is claimed is: 1. A method for acoustic detection of knock in a dual-fuel engine, comprising: determining a gas supplement ratio (GSR) of a mixture of combustible natural gas and diesel fuel; identifying an occurrence of a predetermined start event of a predetermined stroke of a piston of a selected combustion cylinder of the dual-fuel engine; identifying a first observation period that is offset from the occurrence of the predetermined start event, based on the GSR, the first observation period beginning after the predetermined start event, and the first observation period configured to occur during combustion of the diesel fuel in the combustion cylinder; identifying a second observation period that is offset from the occurrence of the predetermined start event, based on the GSR, and at least partly non-overlapping from the first observation period, the second observation period beginning after a beginning of the first observation period, the second observation period configured to occur during combustion of the natural gas in the combustion cylinder; identifying a noise observation period that is non-overlapping from the first observation period and the second observation period, based on the GSR, the noise observation period occurring separate from the combustion of the diesel fuel or the combustion of the natural gas and based on a background noise of the combustion cylinder; and determining a noise metric in the combustion cylinder based on the identified noise observation period; receiving signals, provided by a vibration sensor, representative of vibration of the selected combustion cylinder during the predetermined stroke, wherein receiving signals representative of vibration of the selected combustion cylinder during the predetermined stroke comprises receiving signals during the identified noise observation period; identifying an abnormal combustion event based on the signals; determining that the abnormal combustion event occurred during at least one of the first observation period or the second observation period; and causing a change in operation of the dual-fuel engine based on determining that the abnormal combustion event occurred during at least one of the first observation period or the second observation period. 2. The method of claim 1 , wherein the predetermined start event is based on a piston of the selected combustion cylinder reaching top dead center or a predetermined offset from top dead center. 3. The method of claim 2 , wherein: the first observation period has a start that is offset from the predetermined start event by a first predetermined number of engine crank angle degrees and an end that is offset from the predetermined start event by a second predetermined number of engine crank angle degrees; and the second observation period has a start that is offset from the predetermined start event by a third predetermined number of engine crank angle degrees and an end that is offset from the predetermined start event by a fourth predetermined number of engine crank angle degrees. 4. The method of claim 2 , wherein: the first observation period has a start that is offset from the predetermined start event by a first predetermined amount of time and an end that is offset from the predetermined start event by a second predetermined amount of time; and the second observation period has a start that is offset from the predetermined start event by a third predetermined amount of time and an end that is offset from the predetermined start event by a fourth predetermined amount of time. 5. The method of claim 1 , further comprising providing at least one of a first indicator signal indicative of abnormal combustion of combustible natural gas or a second indicator signal indicative of abnormal combustion of diesel fuel. 6. The method of claim 1 , wherein determining that the abnormal combustion event occurred during at least one of the first observation period or the second observation period further comprises at least one of determining, during the first observation period, that the abnormal combustion event occurred during the first observation period, or determining, during the second observation period, that the abnormal combustion event occurred during the second observation period. 7. The method of claim 1 , wherein determining that the abnormal combustion event occurred during at least one of the first observation period or the second observation period further comprises at least one of determining occurrence of the abnormal combustion event after the first observation period, that the abnormal combustion event occurred during the first observation period, or determining, after the second observation period, that the abnormal combustion event occurred during the second observation period. 8. The method of claim 1 , wherein at least one of identifying the first observation period or identifying the second observation period further comprises performing a table lookup, based on the GSR, on a table of predetermined observation period values. 9. The method of claim 1 , wherein at least one of identifying the first observation period or identifying the second observation period is based on the GSR and at least one of a determined engine load or a determined engine speed. 10. An acoustic knock detection system, comprising: a vibration sensor; a data processing apparatus; and a computer memory storage device storing instructions executable by a computer device and that upon such execution cause the computer device to perform operations comprising: determining a gas supplement ratio (GSR) of a mixture of combustible natural gas and diesel fuel; identifying an occurrence of a predetermined start event of a predetermined stroke of a piston of a selected combustion cylinder of a dual-fuel engine; identifying a first observation period that is offset from the occurrence of the predetermined start event, based on the GSR, the first observation period beginning after the predetermined start event, and the first observation period configured to occur during combustion of the diesel fuel in the combustion cylinder; identifying a second observation period that is offset from the occurrence of the predetermined start event, based on the GSR, and at least partly non-overlapping from the first observation period, the second observation period beginning after a beginning of the first observation period, the second observation period configured to occur during combustion of the natural gas in the combustion cylinder; identifying a noise observation period that is non-overlapping from the first observation period and the second observation period, based on the GSR, the noise observation period occurring separate from the combustion of the diesel fuel or the combustion of the natural gas and based on a background noise of the combustion cylinder; and determining a noise metric in the combustion cylinder based on the identified noise observation period; receiving signals, provided by the vibration sensor, representative of vibration of the selected combustion cylinder of the dual-fuel engine during the predetermined stroke wherein receiving signals representative of vibration of the selected combustion cylinder during the predetermined stroke comprises receiving signals during the identified noise observation period; identifying an abnormal combustion event based on the signals; determining that the abnormal combustion event occurred during at least one of the first observation period or the second observation period; and causing a change in operation of the dual-fuel engine based on determining that the abnormal combustion event occurred during at least one of the first observation period