Background In many jurisdictions, including the United States and Europe, a combined engine and control strategy must receive an emissions compliance certification in order to comply with law. For instance, in the United States the Environmental Protection Agency provides standards that a given engine must meet in order to receive an emission compliance certification. These standards are currently promulgated in the case of off road work machines as requiring a given engine and control strategy to be operated at eight different test points which relate to predetermined combinations of speed and load. The emissions at each of these eight points are then weighted, and the total emissions for the eight test points, as weighted, must fall below a certain level in each of several different emissions categories in order to gain certification. Thus, a given engine and control strategy might have excessive emissions at one test point but may still be compliant if lowered emissions at other test points render the eight point weighted emissions sum acceptable. Thus, engine manufacturers have some flexibility in arriving at a control strategy formula that complies with emissions regulations.

In a typical engine development process, the manufacturer must make assumptions about the expected machine operation and duty cycle before

going forward with the development of a control strategy that satisfies customers' demands while still meeting emissions requirements. For instance, a given engine may have several applications, including over the road trucks and possibly off road work machines, such as bulldozers, wheel loaders, etc. In addition, each of these applications may have a plurality of different identifiable duty cycles.

For instance, an over the road truck may have one duty cycle for on highway driving, another duty cycle for off highway transportation, and still another duty cycle for in town deliveries and pick ups. In another example, a bulldozer might have a first duty cycle for digging, a second duty cycle for scraping, and additional duty cycles for other machine operations. In current engine development processes, the engine manufacturer knows the engine's application, but must make assumptions as to expected duty cycles for an end user.

Currently, an engine and control strategy combination is devised for a specific application with a one size fits all control strategy that is emissions compliant while meeting customer performance demands for each of several different expected duty cycles. In order to make the engine perform satisfactorily in each of the different expected duty cycles, some compromises to the engine control strategy must be made to ensure that the engine can meet the demands of each of the expected duty cycles while satisfying constraints and still meeting emissions standards.

While assumptions in regard to the percentage of time in each of several different duty cycles may be very accurate for one end user, these assumptions could be substantially different from the actual duty cycles of another end user. For instance, one bulldozer owner may perform digging and scraping duty cycles in proportions that correspond closely to an engine manufacturer's assumptions, yet another bulldozer owner may use their work machine almost entirely for digging. Under the current system, both bulldozer owners could have identical engine control strategies. In both cases some amount of compromise in individual customer value is nearly inherent when distributing

an engine control strategy combination that has the ability to satisfy all end user performance demands while still meeting emission requirements.

Summary of the Invention In one aspect, a method is provided for improving a performance parameter for an electronically controlled engine. A plurality of engine control calibration algorithms are made available to the engine control system. An engine control calibration algorithm is selected that corresponds to a predicted engine duty cycle.

Brief Description of the Drawings Figure 1 is a side elevational view of a machine (truck) according to one embodiment of the present invention; Figure 2 is a flow diagram according to one embodiment of the present invention; and Figure 3 is a flow diagram according to another embodiment of the present invention.

Detailed Description Referring to Figure 1, a machine 10 according to one embodiment of the present invention is illustrated for purposes of example as a truck 12.

Nevertheless, those skilled in the art will appreciate that a machine according to the present invention could include"on road"machines, such as the truck <BR> <BR> illustrated, "off road"work machines, such as earth moving equipment<BR> (bulldozers, scrapers, excavators, loaders, backhoes, etc. ), generator sets, or possibly be some other type of machine that includes an electronically controlled internal combustion engine, such as lawn care equipment, for example. Thus, the present invention contemplates virtually any sized engine in virtually any potential application. Although not necessary, the present invention also contemplates that a given engine may have application in more than one machine.

For instance, a given engine may find one application in an over the road truck and another application in a bulldozer. The present invention seeks to exploit what is known, or could be known, about how an engine is used in a particular application. In other words, the present invention seeks to exploit what is known, or could be known, about a given engine's expected duty cycle in order to derive an engine control calibration algorithm that improves performance for the expected duty cycle without violating emissions requirements. Thus, the present invention is potentially applicable to any machine that includes an electronically controlled internal combustion engine. In addition, the present invention contemplates that the control strategy for a given engine in a particular machine must satisfy certain constraints, such as by satisfying emissions limitation standards.

Referring back to Figure 1, truck 12 includes an electronically controlled engine 14 mounted on a chassis 18. A control system 16, which preferably includes a conventional electronic control module, is operably coupled to control the operation of engine 14. In addition, a conveyance 22, which includes a transmission, drive train, wheels, etc. , is operably coupled to engine 14. Those skilled in the art will appreciate that in other applications of the present invention, the machine might include some other implement that is driven by the engine other than the conveyance shown. For instance, one implement could be a generator operably coupled to an engine, or might include earth moving equipment in the case of an off road work machine.

Those skilled in the art will appreciate that control system 16 includes an engine control calibration algorithm that can come in a variety of forms. For instance, an engine control calibration algorithm may be a map of engine control variables verses desired engine operation inputs. For instance, the map may contain variables such as injection timing, injection quantity and rail pressure as a function of a variety of known inputs, such as engine speed, load and other known variables. In addition, an engine control calibration algorithm

might come in the form of equations that are stored in the electronic control module. Those skilled in the art will appreciate that other forms of engine control calibration algorithm's could come in more exotic forms, such as neural networks, or possible even some combination of maps, equations and neural networks.

Thus, the present invention contemplates engine control calibration algorithms in any of a wide variety of forms, that are all equivalent for purposes of the present invention.

Typically, engine control calibration algorithms were often stored in memory available to an electronic control module, and then almost never changed after the particular machine was put into service. In a departure from that accepted methodology, the present invention contemplates making a plurality of different engine control calibration algorithms available to the engine's control system. By making a variety of different engine control calibration algorithms available to the electronic control module, the present invention contemplates that the given machine can be operated in a more efficient manner if the chosen engine control calibration algorithm better matches the duty cycle for the particular machine.

Referring now to Figure 2, the solid lined boxes illustrate one embodiment of the present invention, and the dotted line boxes illustrate an enhanced version of that embodiment of the invention. In this aspect of the invention the truck of Figure 1 preferably has an operator input 20 wherein the operator can choose among several different available duty cycles 30 that reflect how the machine will be operated. For instance, in the case of truck 10 of Figure 1, the operator might be able to choose between a duty cycle corresponding to on highway transport, or a duty cycle for off highway transportation, or possibly another duty cycle for in city deliveries and pick-ups. Thus, the operator can choose among these duty cycles in order to select a predicted duty cycle for that day's operation of the machine. In the next step, a control selection algorithm 32 stored on the electronic control module 34 chooses from among the available

predetermined stored engine control calibration algorithms 36 to match the selected duty cycle. That engine control calibration algorithm is then loaded into the electronic control module 36. Next, the vehicle 12 is operated using that selected engine control calibration algorithm.

In this embodiment of the present invention, each of the predetermined stored engine control calibration algorithms 36 are prepared in a conventional manner, and may include features in common. For instance, it might be that injection quantities for each of the different engine control calibration algorithms 36 are different but the injection timings corresponding to those control calibration algorithms are all the same. Thus, each of the engine control calibration algorithms is derived based upon a predetermined duty cycle 30, and each of the engine control calibration algorithms 36, in conjunction with the engine 14, have an emissions compliance certification. In addition, each of the engine control calibration algorithms 36 can be optimized for some performance parameter, such as fuel economy. Other potential performance parameters include, but are not limited to, reduced undesirable emissions or engine power output considerations. In addition, the engine control calibration algorithms can be optimized for some weighted combination of these performance parameters, but all are made emissions compliant with the given engine. Since the individual control calibration algorithms are based upon some predetermined duty cycle, if the operator operates the machine according to that duty cycle there should be a measurable improvement in the performance parameter over an identical machine operating with a one size fits all control calibration algorithm for all expected duty cycles.

In the illustrated example, each of the engine control calibration algorithms 36 would be preferably based upon one of the predetermined duty cycles and optimized for fuel economy. Thus, provided the operator selects the duty cycle that corresponds to how the machine is actually operated, fuel economy should be improved over an identical machine having a single engine

control calibration algorithm according to the prior art. In order to make the changing between control calibration algorithms more acceptable to agencies such as the Environmental Protection Agency, the process of selecting a predicted duty cycle preferably occurs when the machine is shut down. In addition, this selection process might be performed on some predetermined acceptable schedule, such as once a day or other suitable time period that may be influenced by the particular engine application. For instance, the predetermined schedule for selecting a predetermined duty cycle would likely be different for on highway trucks verses generator sets. Nevertheless, the present invention does contemplate changing between engine control calibration algorithms while the engine is operating, and also contemplates these changes occurring on a more frequent basis, including but not limited to continuously changing the engine control calibration algorithm. Those skilled in the art will appreciate that the selection process might be influenced by how one defines a duty cycle. For instance, an on highway transportation duty cycle might be broken up into separate duty cycles for each of several different speed ranges.

Referring now to the dotted line enhancements to the embodiment of Figure 2, the control system 16 typically has the ability to determine a past duty cycle 38 for that particular machine, and use that information as the predicted duty cycle for how the machine will operate in the future. In other words, this aspect of the invention recognizes that oftentimes the best predictor of a future duty cycle is based upon an accurate reflection of a past duty cycle. In this aspect of the invention, the control system 16 preferably has a means of recording and storing engine operation history 40 data for some predetermined previous time period, which preferably corresponds in some manner to a time duration associated with a particular duty cycle. For instance, the data 40, which would likely include engine speed and load verses time, might reflect a past day in the case of an on highway truck, but might reflect some number of hours of operation in the case of another machine, such as an off road work machine.

Thus, as the machine is operated, data reflecting duty cycle is gathered and stored for use by a duty cycle determiner 38. The previous duty cycle determiner 38 preferably compares the engine operation history data 40 to the predetermined duty cycles, and selects a predicted duty cycle that provides the best match between the engine operation history data 40 and the predetermined duty cycles.

For instance, in the case of the on highway truck illustrated in Figure 1, the engine operation history data might reflect that the truck was operated in an on highway transportation mode over its last duty cycle. The previous duty cycle determiner 38 would recognize this previous duty cycle and select the predicted duty cycle to also be reflective of on highway transportation. Nevertheless, embodiments of the present invention also contemplate that the operator would likely be able to override this automated process such that the operator could choose a predicted duty cycle that is entirely different from that of the immediately preceding duty cycle for the machine. For instance, the operator might recognize that, although the truck operated in an on highway transportation mode for the last several days, for the next day it is going to be operating in an in city delivery and pick-up duty cycle. In that situation, the best fuel economy would be gained not by operating the vehicle while performing in city deliveries using an engine control calibration algorithm optimized for on highway transportation. Rather, this merely reflects that the operator could recognize and act upon the knowledge that that day's duty cycle is going to be different than yesterday's duty cycle.

In still another enhancement to the embodiment of the invention shown in Figure 2, the control system might also have the ability to interpolate 42 between two engine control calibration algorithms 36 that are stored in order to arrive at a hybrid engine control calibration algorithm that is some combination of the discrete control algorithms 36 stored in the control system 16. This interpolation process 42 might be performed in order to provide an even better match between the engine control calibration algorithm and how that machine is

actually operated. For instance, an operator may spend half of each day in an on highway transportation mode while spending the remaining portions of each day in an in city delivery duty cycle mode. Thus, some hybrid control calibration algorithm that is interpolated between the on highway transportation version and the in city delivery version would be best suited for that particular machine. This process of interpolating between two different control calibration algorithms that each is emissions compliant may require approval from a given regulating agency, since the hybrid control calibration algorithm may not ever have been reviewed and approved by the emissions regulating agency. Nevertheless, those skilled in the art will appreciate that if both of the source control calibration algorithms were emissions compliant, a hybrid of the two should also be compliant.

Referring now to Figure 3, another embodiment of the invention is similar to a previously described embodiment in that a plurality of engine control calibration algorithms are made available to the control system. However, this embodiment differs from the earlier embodiment in that the control calibration algorithms are not predetermined and discrete as in the previous embodiment, but are instead derived automatically in the control system 16 itself. In the previous embodiment, certain assumptions still had to be made as to what predetermined duty cycle would be identified around which a control calibration algorithm could be constructed. Like the enhanced version of the previous embodiment, this embodiment contemplates a control system in which engine operation history data is recorded, stored and made available to a duty cycle determiner. Thus, in this embodiment the predicted duty cycle is expected to look a lot like a previous duty cycle. In other words, engine operation history data 40 shows how that particular machine has been operated. This embodiment of the invention assumes that in the future that same machine will be operated in much the same manner. Those skilled in the art will appreciate that some means of weighting the engine operation history data 40 in order to arrive at a predicted duty cycle might

need to be made. For example, engine operation history data 40 that is older and more stale may not be given as much weight as more recent engine operation history data in arriving at a predicted duty cycle 30.

After the control system 16 arrives at a predicted duty cycle 30, the next step is to choose an engine control calibration algorithm from the potential universe of engine control calibration algorithms that corresponds to that predicted duty cycle while satisfying other constraints 42, such as emissions limitations and/or customer specific requirements. The process by which the predicted duty cycle 30 is converted into an engine control calibration algorithm is automated, but performed in much a manner similar to that known in the art for developing an engine control calibration algorithm at the time of manufacture. In other words, an optimizing algorithm 46 is used as the means by which some performance parameter, or weighted group of performance parameters, are optimized in the face of certain constraints. This is typically performed with the aid of an engine simulation model 48. Thus, the control system uses known optimization techniques to converge on an engine control calibration algorithm that optimizes a particular performance parameter while satisfying a variety of known constraints, including but not limited to emissions limitations and customer specific requirements. In the preferred version of this embodiment, the process of determining a previous duty cycle, selecting a predicted duty cycle and determining an engine control calibration algorithm 50 using the optimization algorithm 46 are all preferably performed when the engine 14 is shut down so that the same processor in the electronic control module that controls the engine 14 while in operation determines control calibration algorithms when the engine 14 is not in operation. Like the earlier embodiment, once the control calibration algorithm is determined 50, it is loaded into the electronic control module in a conventional manner, such as a load control algorithm 52 and the engine 14 is then operated according to that control calibration algorithm. Those skilled in the art will appreciate that, providing enough processing power is available, the

process of determining engine control calibration algorithms 50 could be performed while the engine was running. Preferably, the determination of a new control calibration algorithm 50 is performed on some predetermined schedule that is acceptable to a regulating agency, such as the Environmental Protection Agency. In addition, because in this version of the invention the particular engine control calibration algorithms are not specifically identified at the time of engine manufacture, a regulating agency might have to approve the entire process of arriving at a engine control calibration algorithm in order to facilitate the exploitation of this inventive concept.

Industrial Applicability Embodiments of the present invention are applicable to any machine that utilizes an electronically controlled internal combustion engine that is subject to emission compliance certification. Although the present invention maybe most easily envisioned as an improvement to over the road trucks, and reducing fuel consumption in the operation of the same, the present invention could be directed to improving other performance parameters. For instance, in the mining industry emissions from internal combustion engines in the mine may be more important than obtaining the best possible fuel economy. Thus, in that context the performance parameter to be optimized might relate to reducing one or more specific emissions while still meeting other constraints and matching the engine control calibration algorithm to the expected duty cycle for the machine.

Although embodiments of the present invention have been presented in the context of an engine powering a conveyance, the present invention is also applicable to engines operating other implements, including but not limited to earth moving equipment or any other potential implement that is powered directly or indirectly by an electronically controlled internal combustion engine.

In general, embodiments of the invention can be performed in a variety of ways that do not involve any significant departure from known methodologies for determining an engine control calibration algorithm for an

internal combustion engine 14. In other words, an iron set or sets define performance. This performance iron consists of fuel injectors, nozzle variations, cams, pumps, valve timing mechanisms, turbochargers and their variations in housings, wheel designs, waste gate settings, smart waste gates and variable nozzle control variations, etc. Next, data is acquired. This data is used to generate mathematical models for the entire engine 14 and various sub-systems relating to the same. The model can be based solely on selected performance iron or could be generalized to include performance parameters that result from other performance iron, permitting a model to evaluate performance iron combinations that do not yet exist. In addition, the model can be strictly empirical or based on physical principals validated with data. The engine model can take the form of equations (normalized or engineering units in continuous or discontinuous equations), tables, maps, surfaces, neural networks, genetic algorithms, etc.

Thus, an engine control calibration algorithm can come in a wide variety of forms. Possible engine model inputs could include desired speed, actual speed, load, boost, control parameters like injection timing, rail pressure, turbocharger settings, etc. and virtual parameters including but not limited to turbo speed and exhaust temperature. Possible engine model outputs could include emissions, performance parameters including but not limited to fuel consumption, air flows, jacket water and after cooler heat rejections, power output etc.

Thus, the present invention contemplates a method of improving a performance parameter for an electronically controlled engine 14 by making a plurality of engine control calibrations algorithms available to the engine control system. These engine control calibration algorithms are made available to the engine control system either by having complete sets of engine control calibration algorithms stored (Fig. 2) or by providing the tools and data by which a control calibration algorithm from the universe of potential control calibration algorithms can be chosen. Those skilled in the art will also recognize that the control calibration algorithms could also be made available remotely via a suitable

communication such as via telemetry or a phone connection. The engine control calibration algorithm is selected that corresponds to a predicted engine duty cycle, which may be based upon an operator selection and/or engine operation history data. In some versions of the present invention, the predicted engine duty cycle can be based at least in part on a selected machine operation. For instance, if the operator of a bulldozer knows that on that day they will be primarily performing scraping operations, the operator can merely select a scraping duty cycle and the corresponding engine control calibration algorithm for that day's operations.

Those skilled in the art will appreciate that that various modifications could be made to the illustrated embodiment without departing from the intended scope of the present invention. Thus, those skilled in the art will appreciate the other aspects, objects and advantages of this invention can be obtained from a study of the drawings, the disclosure and the appended claims.