Title of Invention

"A SYSTEM FOR DETERMINING CUSTOMIZED FEED FOR AT LEAST ONE ANIMAL"

Abstract A system for determining customized feed for at least one animal, the system comprising: a first memory portion configured to store animal data representative of the characteristics of the animal; a second memory portion configured to store feed data representative of the feed ingredients located at least one location; a third memory portion configured to store evaluation data representative of at least two evaluation criteria; a data processing circuit in communication with the memory portions and configured to generate profile data representative of a nutrient profile for the animal based upon the animal data, the data processing circuit being further configured to generate ration data representative of a combination of ingredients from the location, the ration data being generated by the data processing circuit based upon the profile data, the feed data and the evaluation data; and a fourth memory portion in communication with the data processing circuit, the fourth memory portion being configured to store optirflQ'atiOn weighting data representative of the effect a respective evaluation criteria has on the generation of the ration data, the data processing circuit further generating the ration data based upon the optimization weighting data.
Full Text The present invention relates to a system for determining customized feed for at least one animal.
Field Of The Invention
The present invention relates to a computerized system for determining a customized feed for animals, such as cattle, swine, poultry, fish, crustaceans and the like. In particular, the system determines a feed mix based upon data relating to information such as animal characteristics, available ingredients, speed of product production, and cost of production.
Background
In food production, and specifically producing animal products such as milk, beef, pork, eggs, chicken, fish etc., there is need to improve production efficiency. Production efficiency, i.e. producing the maximum quantity of animal products while minimising the time and cost of production for those products, is important in maintaining a competitive advantage.
A producer (i.e. a farmer, rancher, pork producer, and the like) generally wants to maximize the amount of animal product produced (e.g. gallons of milk, pounds of beef or pork produced) while keeping the costs associated with feed at a low level in order to achieve maximum animal productivity. The maximized amount of anirnal product should be produced at a minimized cost to the producer. Costs to the producer include the cost of feed needed to produce the animal products, as well as the costs of related equipment and facilities needed in the production of animal products. In order to minimize the effect of fixed costs associated with equipment and facilities, the maximum amount of animal product should preferably be produced in a minimum time period.
Producers are constantly trying to increase these production efficiencies. One way of increasing production efficiencies is by altering the feed which animals are fed. For example, a feed with certain amounts of nutrients can cause an animal to grow or produce animal products quickly and/or perform better, whereas a different feed with different amounts of nutrients may cause an animal to grow or produce animal products on a more cost effective basis.


Current systems for creating animal feed are not fully capable of helping producers evaluate and improve production efficiencies. Current systems commonly generate an overall nutrient profile which is related to a set of animal characteristics. Such systems then look at the overall nutrient profile and compare what nutrients may be had from the on-farm ingredients. From this comparison, a "nutritional gap" can be calculated, i.e., the nutritional requirements that the producer needs to fulfill his production goals after accounting for the use of his on-site feed. This nutritional gap is then compared to the nutritional components which may be available from ingredients located at a supplier's mill. Through a comparison of the nutritional gap and the nutritional components available from the mill, current systems allow a supplier to provide a cost effective custom feed which is optimized to permit an animal to produce desired animal products on a cost minimized basis.
Currently systems exist that are capable of taking the amounts of on-farm ingredients to be used hi the overall diet of the animal into account. This is typically done by accounting for the on-farm component of the animal's diet as a fixed input parameter hi the determination. It would be advantageous to be able to modify the amounts of on-farm ingredients to be used hi forming the custom feed as part of the optimization process. Moreover, current systems are generally limited to generating the custom feed based on a single evaluation criteria, typically based on the cost of the feed (e.g., on a cost 6f feed per unit of animal weight gain basis).' It would be advantageous to have a system which is capable of utilizing more than one evaluation criteria hi generating the custom feed.
Summary
One embodiment of the present invention provides a system for determining customized feed for animals, such as farm livestock, poultry, fish and crustaceans. The system stores animal data representative of the characteristics of the animal, feed data representative of the feed ingredients located at one or more locations, and evaluation data representative of at least one evaluation criteria. The evaluation criteria are generally related to factors representative of animal productivity. Examples of evaluation criteria include (i) animal production rate (e.g., the rate of animal weight gain or the rate of production of a food product such as milk or eggs); (ii) cost of feed per unit animal weight gam; and (iii) feed weight per unit animal weight gain. The system includes a data

processing circuit, which may be one or more programmed microprocessors, in communication with a data storage device or devices which store the data. The data processing circuit is configured to generate profile data representative of a nutrient profile for the animals based upon the animal data. In effect, the nutrient profile is a description of the overall diet to be fed to the animals defined in terms of a set of nutritional parameters ("nutrients"). Using the profile data, the data processing circuit generates ration data representative of a combination of ingredients from one or more locations. The ration data is generated by the data processing circuit based upon the profile data, the feed data and the evaluation data.
Another embodiment of the system includes processing means for generating the profile data representative of a nutrient profile for the animals based upon the animal data. Using the profile data the data processing means generates ration data representative of a combination of ingredients from one or more locations. The ration data is generated by the data processing means based upon the profile data, the feed data and the evaluation data.
Another embodiment of the present invention provides a method for determining customized feed for one or more animals. The method includes storing animal data representative of the characteristics of the animal, storing feed data representative of the feed ingredients located a first location (e.g., on farm), storing second feed data representative of the feed ingredients located at a second location (e.g., at a supplier's mill), and storing evaluation data representative of one or more evaluation criteria. Profile data representative of a nutrient profile for the animal is generated based upon the animal data. Using the profile data, ration data representative of a combination of ingredients from one or more locations is generated based upon the profile data, feed data and evaluation data.
Another embodiment of the present invention provides customized feed produced by a process. The process includes storing animal data representative of the characteristics of the animal, feed data representative of the feed ingredients located a location, storing second feed data representative of the feed ingredients located at a second location, and storing evaluation data representative of at least one evaluation criteria. Profile data representative of a nutrient profile for the animal is generated based upon the animal data. Using the profile data, ration data representative of a combination of ingredients from the location is generated based further upon feed data and the evaluation data.

A further embodiment of the present invention provides a food product produced from an animal fed,a customized feed. The food product is produced by a method which includes storing animal data representative of the characteristics of the animal, feed data representative of the feed ingredients located at a location, storing second feed data representative of the feed ingredients located at one or more additional locations, and storing evaluation data representative of at least one evaluation criteria. Profile data representative of a nutrient profile for the animal can be generated based upon the animal data. Using the profile data, ration data representative of a combination of ingredients from one or more of the locations is generated based further upon the feed data and evaluation data. The combination of ingredients is fed to the animal and the animal is appropriately processed to produce the desired food (e.g., a food product such as milk or eggs may be recovered from the animal or the animal may be slaughtered to provide meat for consumption by humans and/or other animals). ,
As modifications to the embodiments described herein, systems and/or methods may rely on more than one optimizing criteria and/or feed data representative of ingredients located at more than one location. For example, ingredients which could be used to create the ration may be located at the farm associated with the animals as well as at the mill of an ingredient supplier. Depending upon the requirements of the system, processing can be
t
consolidated in one processor or divided between processors in communication via a network such as a LAN or the Internet. Furthermore, the processors may be located in devices such as workstations, portable PC's and/or hand held computers.
In other variations of the embodiments described herein, the systems and/or methods may further include a memory portion in communication with the digital processor which stores variation data representative of a range for one or more nutrients of the nutrient profile. The digital processor is capable of generating a set of ration data based upon the variation data. A memory portion of the system may store variation data which corresponds to preselected incremental variations for the values assigned to one or more individual nutrients in the nutritional profile.
Throughout this application, the text refers to various embodiments of the system and/or method. The various embodiments described are meant to provide a variety of exemplary examples and should not be construed as descriptions of alternative species. Moreover, it should be noted that'the descriptions of the various embodiments provided

herein may be of overlapping scope. The embodiments discussed herein are merely illustrative and are not meant to limit the scope of the present invention.
Brief Description Of The Drawings
Figure 1 is a general schematic representation of the data flow hi one embodiment of the present System.
Figure 2 is a general schematic representation of the data flow hi another embodiment of the System which is designed to be used to generate a custom product ("Custom Ration") and/or feed mix from on-site ingredients ("On-Farm Ration") optimized for milk production and/or quality.
Figure 3 is a general schematic representation of the data flow in a variation of the System shown in Figure 1.
Detailed Description
An exemplary system, and process which can be used in producing a customized feed for animals, such as livestock, poultry, fish or crustaceans is described herein. How the system and process can increase production efficiencies by customizing feed is also disclosed. It is particularly desirable if the system and methods are capable of determining an optimized feed using one or more evaluation criteria. Examples of suitable evaluation criteria include a feed cost per unit animal weight gain basis, an animal production rate basis (e.g., based upon a rate of animal weight gain or a rate of production of an animal product, such as milk or eggs), and a feed amount per unit of animal weight gain basis.
In one embodiment of the present system, a computer system may be used which has a processing unit that executes sequences of instructions contained in memory. More specifically, execution of the sequences of instructions causes the processing unit to perform various operations, which are described herein. The instructions may be loaded into a random access memory (RAM) for execution by the processing unit from a read-only memory (ROM), a mass storage device, or some other persistent storage. In other embodiments, hardwired circuitry may be used in place of, or hi combination with, software instructions to implement the present method. Thus, the embodiments described herein are not limited to any specific combination of hardware circuitry and/or software, nor to any particular source for the instructions executed by the computer system.

Creating a customized feed typically involves processing and manipulating at least four basic data sets (see, e.g., Figure 1): first feed data representative of the collection of ingredients located at a first location 1, second feed data representative of the collection ingredients located at a second location 2, animal data representative of characteristics of the animal 3 (e.g., parameters related to its genotype, production level, environment and/or feeding regime), and evaluation criteria 4. As will be explained below, very often first and second feed data representative of sets of ingredients located at an on-fann site (first ingredients 1 located at a first location) and ingredients located at a supplier's mill site (second ingredients 2 located at a second location) are used to generate the recommended mix of ingredients to be fed to the animal. In many instances, the ration data define an overall diet for the animal which includes custom rations from more than one location (e.g., a custom ration from a first location 7 and a custom ration from a second location 8 as depicted in Figure 1). These can be combined to create a customized feed ("ration") which fulfills the animal data requirements while meeting the evaluation criteria 4. The evaluation criteria may be chosen from such suitable criteria related to animal productivity as (i) animal production rate, (ii) cost of feed per unit animal weight gain, and (iii) feed weight per unit animal weight gain.
In some modified embodiments, the present system may include additional memory portions for storing nutrient level constraints 5 and/or ingredient level constraints 6. This may be useful where, for example, it has been established that higher levels of certain nutritional components could pose a risk to the health of an animal being fed the custom feed. For example, if the custom feed includes some trace minerals, such as selenium, present in too great an amount, the custom feed may have adverse health consequences to the animal. Various embodiments of the present invention allow constraints to be placed on the maximum and/or minimum amounts of one or more nutrients in the profile data generated. In some embodiments, this may be used together with the animal data as a basis to calculate the profile data. These constraints may be stored in a memory location as part of the system or the system may permit an individual operator to input one or more constraints on the amount of particular nutrient(s) hi the profile data generated by the system. Similarly, it may be desirable to limit the amounts of one or more ingredients in either a custom product mix or in the overall diet to be fed to the animal. For example, for ease of formulation of a custom feed hi pellet form it may be desirable to limit the amount

of certain ingredients and/or require the inclusion of minimum amounts of specified ingredients.
The first data set that is generally input into the system and subsequently stored in a memory portion includes data representative of characteristics of the animal. Examples of types of data representative of animal characteristics ("animal data") include beginning weight of the animal; a desired weight of the animal; an environment of the animal; a feed form; an actual or desired production level of the animal; and a relationship of animal muscle to fat of the animal. For example, the nutrient profile generated for a particular animal can vary based upon a number of different characteristics of the animal relating to one or more of its genotype, environment, current condition (e.g., defined in terms of health and/or weight), desired production level, feed form (e.g., meal or pellet), current production level, desired final condition (e.g., defined in terms of final weight and/or relationship of animal muscle to fat of the animal) and the like. Tables 1 and 2 below list illustrative sets of animal characteristics which can be used as a basis to generate nutritional profiles to be used in designing custom rations ("custom feeds") for swine and dairy cattle, respectively.
Table 1
Animal Characteristics Suitable for Generating a Nutritional Profile for a Feed for Swine
Animal Category Genotype (lean gain)
Finisher Effective Ambient Temperature
Gilt Replacement Temperature
- Grow Draft
- Prebred Bedding
Sow % of pigs that are wet)
- Gestation Pigs per pen
- Lactation Pig density (square feet per pig)
Artificial Insemination Boar Health
Begin Weight Flooring Type
End Weight Total pigs born/litter
Feed Disappearance (Intake) Litter weight gain
Feed Wastage Total pigs bom/litter
Feed Form

Table 2
Animal Characteristics Suitable for Generating a Nutritional Profile for Dairy Cattle
Target Milk Weight (volume) Body Weight
Target Milk Butterfat % Body Weight Change
Target Milk Protein % Body Condition Score (current)
Current Milk Weight (volume) Body Condition Score (desired)
Current Milk Butterfat % Actual Dry Matter Intake
Current Milk Protein % Environmental Temperature
Percent of group in first lactation Environmental Humidity
Percent of group hi second lactation Genotype
The animal data representative of the characteristics of the animal may be inputted into a computer system with a memory portion available and configured to store the data. The animal data representative of the characteristics of the animal may be inputted into the system by a variety of methods known to those skilled in the art including a keyboard, mouse, touchpad, computer, internet or other related device.
The system includes a data processing circuit which is configured to generate profile data representative of a nutrient profile for the animals based upon the animal data. In effect, the nutrient profile is a description of the overall diet to be fed to the animals defined in terms of a set of nutritional parameters ("nutrients"). Depending on the desired degree of sophistication of the system, the profile data may include a relatively small set of amounts of nutrients or large number of amounts of nutrients. Table 3 includes an illustrative list of nutrients that may be used delineating profile data for animals such as pigs and dairy cattle. Of course, the list of nutrients used hi generating profile data may differ for different types of livestock or other animals Tables 4 and 5 respectively contain lists of nutrients suitable for use hi generating nutritional profiles for swine and dairy cattle, respectively.
The data processing circuit hi the present system is also configured to generate ration data representative of a combination of ingredients from one or more locations. The ration data is generated by the data processing circuit based upon the profile data, feed data representative of the feed ingredients available at the location(s) and evaluation data representative of one or more evaluation criteria.

Table 3
Nutrients Suitable for Generating a Nutritional Profile



Animal Fat
Ascorbic Acid
Biotin
Cal/Phos
Chloride
Choline
Chromium
Cobalt
Copper
Arginine (Total and/or Digestible)
Cystine (Total and/or Digestible)
Isoleucine (Total and/or Digestible)
Leucine (Total and/or Digestible)
Lysine (Total and/or Digestible)
Methionine (Total and/or Digestible)
Phenylalanine (Total and/or Digestible)
Threonine (Total and/or Digestible)
Tryptophan (Total and/or Digestible)
Table 3

Rumres Nfc Salt
Selenium Simple Sugar Sodium Sol Rdp Sulfur Sw Qbs Me Thiamine Total Rdp Verified Adf Verified Ash Verified Calcium Verified Dry Matt Verified Fat Verified Fiber Verified Herai Verified Moisture (Continued)



Valine (Total and/or Digestible)
Folic Acid
Phosphate
Iodine
Iron
Lactose
Lasalocid
Magnesium
Manganese
Monensin
Niacin
Potassium
Protein
Pyridoxine
Rh Index
Riboflavin
Rough Ndf
Rum Solsug

Verified Verified Verified Verified Verified Verified Verified Verified Vitamin Vitamin Vitamin Vitamin Vitamin Vitamin Zinc

Ndf
Neg
Nel
Nem
Nfc
Phos
Protein
Rup
A
B12
B6
D
E
K

Table 4
Nutrients Suitable for Generating a Nutritional Profile for Swine

Biotin Cal/Phos Choline Coppr Add Folic Acid Iodine Add Iron Add Mang Add Niacin Pantotnc Pyridoxine Riboflavin Salt
Selenium Add Sodium Sw Digphos Tbiamine

True Swine Digestible isoleucine
True Swine Digestible lysine
True Swine Digestible methionine
True Swine Digestible threonine
True Swine Digestible tryptophan
True Swine Digestible valine
V Calcium
VPhos
V Protein
VitA
VitD
VitE
VitK
Vitamin B12
Zinc

Table 5
Nutrients Suitable for Generating a Nutritional Profile for Dairy Cattle

Acid Detergent Fiber
Biotin
Calcium
Chloride
Cobalt
Copper
Dietary Cation Anion Difference
Digestible Neutral Detergent Fiber
Dry Matter
Fat
Intestinally Digestible Arginine
Intestinally Digestible Histidine
Intestinally Digestible Isoleucine
Intestinally Digestible Leucine
Intestinally Digestible Lysine
Intestinally Digestible Methionine
Intestinally Digestible Phenylalanine
Intestinally Digestible Threonine
Intestinally Digestible Tryptophan
Intestinally Digestible Valine
Iodine
Iron
Magnesium
Manganese
Neutral Detergent Fiber
Neutral Detergent Fiber from
Roughage
Niacin
Non Fiber Carbohydrates

Non-Protein Nitrogen
Phosphorus
Potassium
Protein
Rumen Degradable Protein
Rumen Undegraded Alanine
Rumen Undegraded Histidine
Rumen Undegraded Isoleucine
Rumen Undegraded Leucine
Rumen Undegraded Lysine
Rumen Undegraded Methionine
Rumen Undegraded Phenylalanine
Rumen Undegraded Protein
Rumen Undegraded Tryptophan
Rumen Undegraded Valine
Salt
Selenium
Sodium
Soluble Protein
Soluble Sugar
Starch
Sulfur
Verified Net Energy for Lactation
Vitamin A
Vitamin D
Vitamin E
Zinc

Evaluation criteria are typically related to factors representative of animal productivity and reflect an aspect of production a producer would like to optimize. The present system allows a producer to select evaluation criteria (e.g. cost/gain, cost/output, animal production rate, and/or feed/gain) which fits the producer's production goals. For example, a dairy producer may focus on the cost of feed required to produce a unit of output (cost/output), whereas a pork producer may focus on cost/gain or rate of gain.

Examples of suitable animal production criteria which may be used as evaluation criteria in the generation of ration data include (i) animal production rate, (ii) the cost of feed per unit animal weight gain, and (iii) the feed weight per unit animal weight gain. The animal production1 rate may simply be a measure representative of the rate of weight gain of the animal in question (rate of gain). For example, a pork producer may wish to optimize rate of gain by selecting a feed which maximizes the rate at which a pig gains weight. This could be selected if a pig farmer was interested in turning over production as quickly as possible in a fixed asset which has limited space. The evaluation data may include data representative of the cost of feed required to produce a Unit of weight gain of the animal ("cost/gain" basis). For example, a pork producer may wish to optimize cost/gain by selecting a feed which minimizes the feed cost required to make a pig gain a unit of weight. The evaluation data can include data representative of the amount of feed required to produce a unit of gain (feed/gain). For example, a producer may wish to optimize the feed/gain by selecting a feed which minimi7.es the amount of feed required to produce a unit of gain. A producer might select this criterion if they were faced with feed storage space constraints.
Examples of other suitable animal production rates which may be used as an evaluation criteria include rates of production of food products, such as milk or eggs, from the animal. Other suitable evaluation criteria include the cost of feed required to produce a unit of output of a particular animal product ("cost/output"). For example, a milk producer may wish to optimize the cost/output by selecting a feed which Tninimi7.es the cost of feed required to produce a unit of milk. In addition to utilizing evaluation data representative of only a single evaluation criteria, the present system may be capable of using evaluation data representative of a combination of two or more evaluation criteria in generating the ration data. For example, when considering an appropriate feed, a producer may wish to generate a custom feed based on the rate of production as well as cost of the feed (typically on a cost/gain basis).
Furthermore, the producer may choose to weight the relative contributions of two or more evaluation criteria. The system may include a data processing circuit which generates ration data based in part upon a weighted average of more than one evaluation criteria. In one specific embodiment, the system generates ration data based in part upon a 70:30 weighted average of two evaluation criteria (primary and secondary), such as a combination

of cost of feed per unit animal weight gain and animal production rate. The system may also allow a user to alter the relative weighting accorded to the various evaluation criteria selected.
For instance, hi the example referred to above, the producer may want to generate ration data using a combination of evaluation criteria that is weighted 70% on a cost/gain basis and 30% on a irate of animal weight gain basis. One method for providing such a weighted optimization analysis is to generate one solution for ration data using cost/gain as the sole evaluation criteria and generating a second for ration data using rate of animal weight gain as the sole evaluation criteria. Ration data Which is representative of the weighted combined solution can be achieved by summing 70% of the amounts of ingredients from the cost/gam ration data set and 30% of the amounts of ingredients from the rate of gam ration data set. For example, in the instance where cost/gain ration data (generated solely on a cost/gain basis) includes 10% dehulled corn meal, and rate of gain ration data (generated solely on a rate of gain basis) includes 15 % dehulled corn meal, if a producer chose cost/gain as the primary evaluation criteria the ingredient mix hi the diet will include roughly 70% of the 10% dehulled corn meal requirement, and 30% of the 15%" dehulled corn meal requirement summed to produce the amount of dehulled corn meal hi the overall diet (i.e., circa 11.5% dehulled corn meal). This weighted summation is then repeated for all the amounts of ingredients present hi the two custom diets generated by the two approaches. As one skilled hi the art will recognize, there are other methods of generating ration data based on a weighted combination of evaluation criteria. The present system can also be configured to generate ration data based on other weightings of combinations of two or more evaluation criteria (e.g., two evaluation criteria weighted on either a 60:40 or 80:20 basis). In some embodiments of the present system, the weighting factors assigned to various evaluation criteria can themselves be input parameter(s) chosen by a producer to reflect the needs of his/her particular situation.
Figure 2 depicts the general flow of data hi one embodiment of the present system. The system shown in Figure 2 includes a data processing circuit 30 configured to generate a nutrient profile 32 based on the animal data 31 and optional adjustments which may be provided by a nutritionist. Other data processing circuits generate lists of nutrient amounts associated with individual ingredients available at an on-farm site 33 and manufacturing site 34. A data processing circuit 36, which includes a linear program generates a custom

product based on evaluation criteria 35. The linear program typically also generates the custom product solution based on pricing data associated with both the on-farm and manufacturing site ingredients. In one embodiment, retail and wholesale pricing information may be normalized to allow the linear program to facilitate consideration of potential ingredients with different types of associated prices as the basis for a solution to a single multivariable problem. The linear program is a mathematical model capable of solving problems involving a large number of variables limited by constraints using linear math functions. A variety of different linear programs capable of solving problems of this type are known to those of skill hi the art. One example of a program of this type is commercially available from Format International as part of computer software system for solving complicated multivariable problems.
Memory portions of the systems which store animal data, evaluation data, and feed data representative of on-hand ingredients and/or mill ingredients are hi communication with a data processing unit capable of generating ration data. The data processing unit can include a data processing circuit or a digital processing circuit. The memory portions which store the animal data, feed data for on-hand and mill ingredients, and evaluation data may be in communication with the data processing unit by inputted keyboard commands, mouse commands, a network connection with another computer, personal data assistants, via a modem connection, via an internet, or via an intranet.
Data processing circuit(s) which include the linear program can take input data (e.g., profile data, feed data, evaluation data and ingredient constraint data) as a basis to compute ration data. Ration data includes data specifying a combination of ingredients solution which is solved to fulfill a desired nutrient profile based on one or more evaluation criteria. Ration data generated by the present system generally includes data representative of the types and amounts of ingredients to be used to provide an overall custom diet for an animal. The ration data provided by .the system generally also specifies a solution that is described in terms of a combination of types and amounts of ingredients from a first location (e.g., an on-farm location) and types and amounts of ingredients from at least one additional site (e.g., one or more supplier locations). Where the overall set of potential ingredients includes ingredients located at more than one location, the custom feed specified by the ration data may be made of ingredients located at either a single location or from more than one location. For example, the ration data may define a custom feed made up

from ingredients located solely at supplier location or made up from ingredients located at both an on-farm location and a supplier location.
The ration data generally include custom feed data representative of a combination of amounts of the feed ingredients. The custom feed data may specify the type and corresponding amounts of the ingredients to be used in formulating the overall diet of an animal. This may be made up from a set of ingredients available at more than one location, e.g., from ingredients available at a producer's site and as well as ingredients available at a supplier location. The present system may also provide custom feed data which specifies the types and amounts of ingredients to be used from individual locations. For example, the custom feed data may include a listing of the types and amounts of ingredients available at a first location (e.g., on-farm ingredients) to be used to form a first feed mix and a listing of the types and amounts of ingredients available at a second location (e.g., ingredients available at a supplier location) to be used to form a second feed mix. In such instances, the custom feed data will typically also specify the amounts of the first and second feed mixes that are to be used to make up the overall custom diet for an animal.
The ration data typically includes amounts of a variety of types of ingredients. The actual ingredients available at any particular location can vary over tune and will generally vary on a regional basis as well as reflect the type of animal feed that is typically produced and/or stored at the particular site. Commonly, the ration data include feed data' representative of amounts of ingredients from a number of different ingredient categories, such as a gram source, a protein source, a vitamin source, a mineral source (e.g., a macromineral source and/or a trace mineral source) and/or a fat source. Table 6 includes a list of exemplary ingredients suitable for use hi formulating custom feed mixes for a variety of animals. Tables 7, 8 and 9 include lists of ingredients which may be used hi generating custom feed products for swine or dairy cattle.

Table 7
Ingredients Suitable for Use in Producing a Custom Feed for a Finishing Diet for Swine
Alimet Linseed Meal
Bakery Product L-Lysine HC1
Beet Pulp Lt. Barley
Brewers Rice L-Threonine
Brown Sugar Malt Sprouts
Calcium Carb Meat And Bone Meal
Cane Sugar Menhaden Fish
Canola Meal Molasses
Cereal Fines Mono-Dical Phos
Cg Feed Monosod Phos
Choline Oat Mill Byproducts
Copper Sulfate Oat Mill Byproducts
Corn - Ground Fine Oats - Ground
Cora Gluten Meal Oats - Rolled
Corn Oil Pork Bloodmeal
Corn Starch Safflower Meal
Dehydrated Alfalfa Salt
Distillers Grains With Soil Selenium
Dried Potato Waste Soybean Hulls
Dynasol Soybean Meal
Fat Soybean Oil
Fat Sprayed Sunflower
Feather Meal Tryptosin
Feeding Rate Wheat Midds
Fish Meal

Table 8
Ingredients Suitable for Use in Producing a Custom Feed for Breeding Swine

Alimet
Animal Fat
Ascorb Acid
Bakery Product
Bentonite
Blood Meal - Beef/Pork
Calcium Carbonate
Cereal'Fines
Choline Chloride
Copper Sulfate
Cora Germ Meal
Cora Gluten Feed
Distillers Grains With Solubles
Dry Methionine Hydroxy Analog
Fish Meal
Malt Sprouts
Meat And Bone Meal; Pork Carcass

Methionine
Mineral Oil
Molasses-Cane
Mono-Dicalcium Phosphate
Oat Hulls
Red Flavor
Rice Bran
Salt
Selenium
Soybean Hulls
Threonine
Tryptophan
Vitamin E
Wheat Midds
Wheat Starch
Zinc Oxide
Zinc Sulfate

Table 9
Ingredients Suitable for Producing a Custom Feed for Dairy Cattle



Calcium Carbonate
Copper Sulfate
Cora Gluten Meal
Fat
Magnesium Oxide
Meat And Bone Meal, Pork
Mono-Dical Phos
Niacin
Pork Blood Meal
K/Mg/Sulfate
Yeast

Salt
Selenium
Sodium Sesquicarbonate
Soybean Hulls
Soybean Meal
Trace Minerals
Urea
Vitamin-E
Wheat Midds
Zin-Pro

When feeding animals, producers may not be able to satisfy nutritional requirements of the annuals solely using on-hand ingredients (e.g., on-farm ingredients). To satisfy the animal's nutritional requirements, producers may desire to use on-hand ingredients in conjunction with a custom feed product made up of feed ingredients available from an

outside supplier, such as a mill, feed mixer, and the like. The outside supplier will commonly have a range of ingredients available or on hand in their inventory (e.g., corn in various forms, soybean meal, wheat mids, barley, oats, animal fat, various vitamin supplements).
In addition to data specifying the types and amounts of ingredients to be used to provide the overall custom diet for an animal, the ration data generated by the present system can also include other data associated with the overall custom diet. Examples of such other data include cost data representative of a cost associated with the custom feed data, feed weight data representative of a feed weight associated with the custom feed data, and performance data representative of projected animal performance associated with the custom feed data. For example, Table 10 below lists a number of categories of ration data that may be useful in assisting a producer and/or supplier in evaluating a custom feed with respect to productivity, animal performance and cost effectiveness. The availability of these types of information can provide a producer and/or supplier with additional information concerning the effects of variations in dietary composition on factors such as cost, volume of feed, wastage and animal performance. As with the listing(s) of the types and amounts of ingredients, the cost data and feed weight data can be representative of costs and feed weights associated with the overall custom diet and/or with feed mix(es) to be provided from individual locations.
Table 10
Illustrative Categories of Ration Data Associated with a Custom Feed for Swine
End Weight Lean Gain
Days in Phase Lean %
Avg Daily Gain Effective Ambient Temp
Avg Daily Feed Intake Cost of Gain
Total Feed Consumed Total Cost per phase
Feed/Gain
In other variations of the embodiments described herein, the systems and/or methods may also include a memory portion in communication with the digital processor which stores variation data representative of a range for one or more nutrient components

of the nutrient profile. The digital processor is capable of generating a set of ration data based upon the variation data. The memory portion may store variation data which correspond to preselected incremental variations for the values assigned to one or more individual nutrients in the nutritional profile. For example, memory portion may store variation data which correspond to preselected incremental positive and negative variations of the values assigned to two individual nutrients, such as true digestible lysine and net energy. The digital processor would generate ration data corresponding to each of the eight possible additional combinations of values for the two specified nutrients. Together with the ration data associated with the original nutritional profile, the resulting set of nine ration data corresponding to the various combinations of values for each specified nutrient (original value, original value plus an increment; original value minus an increment) would make up a three by three matrix of ration data. One example of this approach is illustrated in Table 11 below. A general approach to generating a set of ration data based upon variation data is depicted schematically in Figure 3. The determination of ration data for the center point in the matrix ("Ration Data 5") corresponds to the solution generated by the data processing circuit based on the nutrient profile. In the example shown in Table 11, the nutrient profile has values of 0.90% for true digestible lysine and 2150 kcal/kg for net energy. Each of the eight other ration data in the set depicted hi Table 11 corresponds to a ration data generated far a modified nutrient profile in which the value for at least one . nutrient has been varied by a specified increment. For example, Ration Data 1 represents ration data associated with a modified nutrient profile has values of 0.95% for true digestible lysine and 2100 kcal/kg for net energy. Ration Data 6 represents ration data associated with a modified nutrient profile in which only the value for true digestible lysine (0.85 %) has been varied from the values in the nutrient profile. The generation of such a matrix can facilitate an evaluation of the effect of incremental variations in amounts of
t
specified nutrient(s) on the assessment of optimum ration data for a given evaluation criteria.

Table 11 True Digestible Lysine
0.95% 0.90% 0.85%
2100 Ration Data 1 Ration Data 2 Ration Data 3
Net
Energy 2150 Ration Data 4 Ration Data 5 Ration Data 6
(kcal/kg)
2200 Ration Data 7 Ration Data 8 Ration Data 9
The invention has been described with reference to various specific and illustrative embodiments and techniques. However, it should be understood that many variations and modifications may be made while remaining within the spirit and scope of the invention.

Table 6
Exemplary Ingredients Suitable for Use in Formulating Custom Feed Mixes

Acidulated Soap Stocks
Active Dry Yeast
Alfalfa Meal
Alfalfa-Dehydrated
Alimet
Alka Culture
Alkaten
Almond Hulls
Ammonium Chloride
Ammonium Lignin
Ammonium
Polyphosphate
Ammonium Sulfate
Amprol
Amprol Ethopaba
Anhydrous Ammonia
Appetein
Apramycin
Arsanilic Acid
Ascorb Acid
Aspen Bedding
Availa
Avizyme
Bacitracin Zinc
Bakery Product
Barley
Barley-Crimped
Barley-Ground
Barley-Hulless
Barley-Hulls
Barley-Midds
Barley-Needles
Barley-Rolled
Barley-St. Bon.
Barley-Whole
Barley-With Enzyme
Baymag
Beef Peanut Hulls
Beef Peanut Meal
Beet
Beet Pulp
Biotin

Biscuit By Product
Black Beans
Blood-Rash Dry
Blueprint Rx
Bone Meal
Brewers Rice
Brix Cane
Buckwheat
Bugs
Cage Calcium
Calcium Cake
Calcium Chloride
Calcium Formate
Calcium lodate
Calcium Sulfate
Calciun Prop
Calf Manna
Canadian Peas
Cane-Whey
Canola Cake
Canola Fines
Canola Meal
Canola Oil
Canola Oil Blender
Canola Oil Mix
Canola Screenings
Canola-Whole
Carbadox
Carob Germ
Carob Meal
Cashew Nut By Product
Catfish Offal Meal
Choline Chloride
Chromium Tripicolinate
Citrus Pulp
Clopidol
Cobalt
Cobalt Carbonate
Cobalt Sulfate
Cocoa Cake
Cocoa Hulls
Copper Oxide

Copper Sulfate Corn Chips Corn Chops Corn Coarse Cracked Corn- Coarse Ground Corn Cob-Ground Corn Distillers Corn Flint Corn Flour Corn Germ Bran Corn Germ Meal Corn Gluten Cora- High Oil Corn Kiblets Cora Meal Dehulled Com Oil Com Residue Corn Starch Corn/Sugar Blend Corn-Cracked Corn-Crimped Corn-Ground Fine Corn-Ground Roasted Corn-Steam Flaked Corn-Steamed Corn-Whole Cottonseed Culled Cottonseed Hull Cottonseed Meal Cottonseed Oil Cottonseed Whole Coumaphos Culled Beans Danish Fishmeal Decoquinate Dextrose
Diamond V Yeast Disodium Phosphate Distillers Grains Dried Apple Pomace Dried Brewers Yeast Dried Distillers Milo

Table 6 - (Continued)

Dried Porcine
Dried Whole Milk
Powder
Duralass
Enzyme Booster
Epsom Salts
Erythromycin
Extruded Grain
Extruded Soy Flour
Fat
Feather Meal
Feeding Oatmeal
Fenbendazole
Fermacto
Ferric Chloride
Ferrou Cabonate
Ferrous Carbonate
Ferrous Sulfate
Fine Job's Tear Bran
Fish Meal
Fish
Flavoring
Folic Acid
French Fry Rejects
Fresh Arome
Fried Wheat Noodles
Gold Dye
Gold Flavor
Grain Dust
Grain Screening
Granite Grit
Grape Pomace
Green Dye
Green Flavor
Guar Gum
Hard Shell
Hemicellulose Extract
Hemp
Herring Meal
Hominy
Hygromycin
Indian Soybean Meal
Iron Oxide-Red
Iron-Oxide Yellow
Job's Tear Broken Seeds
Kapok Seed Meal
Kelp Meal

Kern Wet
Lactose
Larvadex
Lasalocid
Levams Hcl
Limestone
Linco
Lincomix
Lincomycin
Linseed Meal
Liquid Fish Solubles
Lupins
Lysine
Magnesium
Magnesium Sulfate
Malt Plant By-Products
Manganous Ox
Maple Flavor
Masonex
Meat And Bone Meal
Meat And Bone Meal
Meat Meal
Mepron
Methionine
Millet Screenings
Millet White
Millet-Ground
Milo Binder
Milo-Coarse Ground
Milo-Cracked
Milo-Whole
Mineral Flavor
Mineral Oil
Mixed Blood Meal
Molasses
Molasses Blend
Molasses Dried
Molasses Standard Beet
Molasses Standard Cane
Molasses-Pellet
Mold
Monensin
Monoamonum Phos
Monosodium Glutamate
Monosodium Phosphate
Mung Bean Hulls
Mustard Meal High Fat

Mustard Oil
Mustard Shorts
Narasin
Natuphos
Niacin
Nicarbazin
Nitarsone
Oat Gullets
Oat Flour
Oat Groats
Oat Hulls
Oat Mill Byproducts
Oat Screenings
Oat Whole Cereal
Oatmill Feed
Oats Flaked
Oats-Ground
Oats-Hulless
Oats-Premium
Oats-Rolled
Oats-Whole
Oyster Shell
Paddy Rice
Palm Kernel
Papain
Papain Enzyme
Paprika Spent Meal
Parboiled Broken Rice
Pea By-Product
Pea Flour
Peanut Meal
Peanut Skins
Pelcote Dusting
Phosphate
Phosphoric Acid
Phosphorus
Phosphorus
Defluorinated
Pig Nectar
Plant Waste
Poloxalene
Popcorn
Popcorn Screenings
Porcine Plasma; Dried
Pork Bloodmeal
Porzyme
Posistac

Table 6 - (Continued)

Potassium Bicarbonate
Potassium Carbonate
Potassium Magnesium
Sulfate
Potassium Sulfate
Potato Chips
Poultry Blood/Feather
Meal
Poultry Blood Meal
Poultry Byproduct
Predispersed Clay
Probios
Procain Penicillen
Propionic Acid
Propylene Glycol
PyranTart
Pyridoxine
Quest Anise
Rabon
Rapeseed Meal
Red Flavor
Red MUlet
Riboflavin
Rice Bran
Rice By-Products
Fractions
Rice Dust
Rice Ground
Rice Hulls
Rice Mill By-Product
Rice Rejects Ground
Roxarsone
Rumen Paunch
Rumens in
Rye
Rye Distillers
Rye With Enzymes
Safflower Meal
Safflower Oil
Safflower Seed
Sago Meal
Salinomycin
Salt
Scallop Meal
Seaweed Meal
Selenium
SheU Aid

Shrimp Byproduct
Silkworms
Sipernate
Sodium Acetate
Sodium Benzoate
Sodium Bicarbonate
Sodium Molybdate
Sodium Sesquicarbonate
Sodium Sulfate
Solulac
Soweena
Soy Flour
Soy Pass
Soy Protein Concentrate
Soybean Cake
Soybean Curd By-
Product
Soybean DehuUed Milk
By-Product
Soybean Hulls
Soybean Mill Run
Soybean Oil
Soybean Residue
Soybeans Extruded
Soybeans-Roasted
Soycorn Extruded
Spray Dried Egg
Standard Micro Premix
Starch Molasses
Steam Flaked Corn
Steam Flaked Wheat
Sugar (Cane)
Sulfamex-Ormeto
Sulfur
Sulfur
Sunflower Meal
Sunflower Seed
Tallow Fancy
Tallow-Die
Tallow-Mixer
Tapioca Meal
Tapioca Promeance
Taurine
Terramycin
Thiabenzol
Thiamine Mono
Threonine

Tiamulin
Tihnicosin
Tomato Pomace
Trace Min
Tricalcium Phosphate
Triticale
Tryptophan
Tryptoshie
Tuna Offal Meal
Tylan
Tylosin
Urea
Vegetable Oil Blend
Virginiamycin
Vitamin A
Vitamin B Complex
Vitamin B12
Vitamin D3
Vitamin E
Walnut Meal
Wheat Bran
Wheat Coarse Ground
Wheat Germ Meal
Wheat Gluten
Wheat Meal Shredded
Wheat Millrun,
Wheat Mix
Wheat Noodles Low Fat
Wheat Red Dog
Wheat Starch
Wheat Straw
Wheat With Enzyme
Wheat-Ground
Wheat-Rolled
Wheat-Whole
Whey Dried
Whey Permeate
Whey Protein
Concentrate
Whey-Product Dried
Yeast Brewer Dried
Yeast Sugar Cane
Zinc
Zinc Oxide
Zoalene



We claim:
1. A system for determining customized feed for at least one animal, the system comprising:
a first memory portion configured to store animal data representative of the characteristics of the animal;
a second memory portion configured to store feed data representative of the feed ingredients located at least one location
a third memory portion configured to store evaluation data representative of at least two evaluation criteria;
a data processing circuit in communication with the memory portions by network, keyboard or mouse inputted commands and configured to generate profile data representative of a nutrient profile for the animal based upon the animal data, the data processing circuit being further configured to generate ration data representative of a combination of ingredients from the location, the ration data being generated by the data processing circuit based upon the profile data, the feed data and the evaluation data; and
a fourth memory portion in communication with the data processing circuit, the fourth memory portion being configured to store optimization weighting data representative of the effect a respective evaluation criteria has on the generation of the ration data, the data processing circuit further generating the ration data based upon the optimization weighting data.


Documents:

00871-delnp-2003-abstract.pdf

00871-delnp-2003-assignment.pdf

00871-delnp-2003-claims.pdf

00871-delnp-2003-correspondence-others.pdf

00871-delnp-2003-description (complete)-19-05-2008.pdf

00871-delnp-2003-description (complete)-24-05-2008.pdf

00871-delnp-2003-description (complete).pdf

00871-delnp-2003-drawings.pdf

00871-delnp-2003-form-1.pdf

00871-delnp-2003-form-18.pdf

00871-delnp-2003-form-2.pdf

00871-delnp-2003-form-5.pdf

00871-delnp-2003-gpa.pdf

00871-delnp-2003-pct-105.pdf

00871-delnp-2003-pct-304.pdf

00871-delnp-2003-pct-332.pdf

00871-delnp-2003-pct-401.pdf

00871-delnp-2003-pct-408.pdf

00871-delnp-2003-pct-409.pdf

00871-delnp-2003-pct-416.pdf

00871-delnp-2003-pct-request form.pdf

00871-delnp-2003-pct-search report.pdf

871-DELNP-2003-Abstract-19-05-2008.pdf

871-delnp-2003-claims-(24-05-2008).pdf

871-DELNP-2003-Claims-19-05-2008.pdf

871-delnp-2003-correspondence-others-(24-05-2008).pdf

871-DELNP-2003-Correspondence-Others-19-05-2008.pdf

871-DELNP-2003-Correspondence-Others-22-05-2008.pdf

871-DELNP-2003-Drawings-19-05-2008.pdf

871-DELNP-2003-Form-1-19-05-2008.pdf

871-DELNP-2003-Form-2-19-05-2008.pdf

871-delnp-2003-form-3-22-05-2008.pdf

871-DELNP-2003-GPA-19-05-2008.pdf

871-delnp-2003-petition-137-22-05-2008.pdf

871-delnp-2003-petition-138-22-05-2008.pdf


Patent Number 221953
Indian Patent Application Number 00871/DELNP/2003
PG Journal Number 32/2008
Publication Date 08-Aug-2008
Grant Date 11-Jul-2008
Date of Filing 05-Jun-2003
Name of Patentee CAN TECHNOLOGIES INC.,
Applicant Address 12900 WHITEWATER DRIVE, MINNETONKA, MN 55343, UNITED STATES OF AMERICA
Inventors:
# Inventor's Name Inventor's Address
1 STEVE R. BURGHARDI` 8230 DREXEL COURT, EDEN PRAIRIE, MN 55347, USA
2 BRIAN J. KNUDSON 7312 FAUN HILL ROAD, CHANHASSEN, MN 55317, USA
3 LOREN PETERSON 8036 DAVIS STREET, LORETTO, MN 55357, USA
4 DAVID A. COOK 12162 UNITY CIRCLE NW, COON RAPIDS, MN 55448, USA
5 MARK A. OEDEKOVEN 4932 ALDRICH, MINNEAPOLIS, MN 55430, USA
PCT International Classification Number A01K 5/00
PCT International Application Number PCT/US01/48080
PCT International Filing date 2001-12-13
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 09/739,550 2000-12-15 U.S.A.