The present invention relates to a method and apparatus for the remote sensing of animals using thermographic sensing technology and computer software for analysis and presentation of thermographic data obtained.

Currently in agriculture there are some bottlenecks that impede further advances in production efficiency and animal health and welfare. Growth monitoring is currently done using inventory analysis and physical weighing of animals. These procedures are invasive (ie. disrupt the everyday life and growth of the livestock) , labour intensive, and prone to human error. Advances in growth monitoring would enhance our knowledge of animal production, and would allow producers in the field to identify inefficiency in their operations.

A second major bottleneck is the identification of animals which develop diseases that reduce growth and performance. Currently disease diagnosis depends primarily on human recognition of the signs. This recognition is limited by the experience and ability of the person examining the animal and the time-and-labour allotted to screening for disease.

Livestock production would be enhanced if current technology could be refined to do some of the above tasks, eg. with instruments that would remotely sense farm animals and determine their quantity, location, temperature and body mass. Such could be applied to livestock production where accurate animal inventories and daily growth rates are difficult to obtain. Pig farms estimate growth rates over the marketing period (6 months) . Poultry farms monitor growth by weighing a random subset of birds on a regular basis. Beef feedlots spend a lot of time and money examining incoming cattle for respiratory disease. Any advances in automating these processes would be

extremely useful. Large swine operations have inventories of many thousands of animals. Any technology that would enhance the monitoring of animals would also be welcomed by the industry.

With the advent of efficient microprocessor technology, remote sensing of objects has been developed for commercial manufacturing processes. Using mechanical and electronic means of determining characteristics such as size, shape, colour, texture, etc. allows for less dependence on human input, and ultimately leads to more efficient handling and processing methods. In some cases, remote sensing and measuring can add a level of precision beyond human capability.

Precise measurements of animals are desired in many livestock operations in order to monitor production.

For example, the weight and temperature of animals are important in assessing production rates, presence of disease, environmental conditions etc. In using traditional techniques, obtaining such measurements involves handling animals individually, which can be manually demanding and time consuming. Ideally, a method of obtaining such measurements remotely, ie. without manually handling each animal individually, and readily upon the demand of a livestock operation worker, would be substantially beneficial.

We have now found a method and apparatus that can be used for remotely sensing animals, in one aspect, a livestock operation and to provide for example, weight and temperature data on demand, or continuously if desired. These rely in part on thermographic sensing technology. Thermographic technology has been adapted for many temperature sensing purposes, eg. in medicine for detecting inflammation or other pathological conditions of humans, as disclosed in U.S. Patent No.5,056,525. It has also been used in the diagnosis of pathological conditions in

animals, as exemplified in the paper: Hurnik, J.F., De Boer, S. , and Webster, A.B. , Detection of Health Disorders in Dairy Cattle Utilizing a Ηiermal Infrared Scanning Technique, Can.J.Anim.Sci. 64: 1071-1073. However, such and other uses to date have been for the analysis of specific animals under specific care or attention, and not performed remotely on animals on a surveillance or continuous basis.

Summary of the Invention

The invention provides an apparatus for remote sensing of information about an animal in an area and making said information available to a person in a decipherable form. The information may be production information about livestock, or health status information of animals in a zoo, for example. The apparatus in a broad aspect comprises a means for remotely obtaining a thermographic image of the area, which image can be used directly or indirectly to provide an absolute or relative temperature of an animal in the area. There is also a means for converting the image into computer readable form, a means for interpreting that form to provide the information, and a means for displaying the information in a person-decipherable form, eg. in a form with meaning to a livestock manager or zoo-keeper.

The means for converting the image into computer readable form preferably includes a means for converting the image into a number array, each number having a position corresponding to a pixel in the image and a value corresponding to a relative brightness of the pixel. This may be accomplished on a video-digitizer circuit board.

Preferably, the means for remotely obtaining the thermographic image of the area is a thermographic imaging camera. The camera is preferably mountable on a means for moving the camera from over one area to another, so that animals in different areas may be viewed selectively. The

means for moving the camera preferably includes a track, extending over two or more different areas. The camera is preferably slideably mounted on the track.

In another preferred embodiment of the apparatus using a thermographic imaging camera, the camera is fixable to view only one area, eg. a temporary holding pen for animals for slaughter. Livestock in such area would be changed regularly, so a fixed camera would be sufficient in such context.

The means for interpreting the computer readable form to provide the information preferably includes processing means for segmenting a group of pixels associated with an animal in the area from pixels associated with background and applying a unique identifier to the animal profile. The processing means also preferably includes one or more of the following: means for segmenting a single group of pixels associated with a plurality of animals and determining an approximation of a number of animals associated with the single group of pixels; means for counting the unique identifier and the approximation of a number of animals associated with the single group of pixels to determine an estimate of a number of animals in the area; means for counting a total number of pixels in an animal profile to determine an approximate weight of an associated animal in the area; means for determining a centre of an animal from locations of all pixels in an associated animal profile and then determining an approximate position of the animal in the area; means for determining an approximate absolute or relative temperature of an animal in the area based on average brightness of pixels in an associated animal profile; means for determining an estimate of carcass 24 hour pH from the approximate (pixel) temperature variation of an animal before slaughter; means for determining an estimate of visual PSE meat score from the approximate (pixel) temperature of an animal before slaughter; and means for

determining an approximate absolute or relative temperature of background to animals in the area based on average brightness of pixels in the background.

In another aspect there is provided a method of remotely sensing information about an animal in an area, which comprises obtaining a thermographic image of the area, wherein the image directly or indirectly is able to provide an absolute or relative temperature of an animal in the area, converting the image into computer readable form, interpreting the form to provide the information, and displaying the information in a person-decipherable form.

Brief Description of the Drawings

In the accompanying drawings which illustrate preferred embodiments of the present invention: FIG. 1 is a perspective view of an apparatus, according to the present invention, in use in monitoring pigs;

FIG. 2 is a graph of actual weight (scale weight) of various pigs vs pixel weight (weight determined from pixel values obtained by thermographic image analysis) in a study of applying the present invention to pigs;

FIG. 3 is a graph of actual skin temperature of various pigs vs pixel temperature ( temperature determined from pixel values obtained by thermographic image analysis) in a study of applying the present invention to pigs;

FIG. 4 is a flow chart of one example of basic thermographic sensing operations that may be employed under the present invention;

FIG. 5 is a graph of actual vs pixel carcass pH in a study of applying the present invention to pigs; and

FIG. 6 is a graph of PSE (Pale Soft Exudative meat) score-vs pixel temperature in a study of applying the present invention to pigs.

Detailed Description of Preferred Embodiments

We have developed a method for the remote sensing of animals using a thermographic image sensing system. The method involves sensing the presence of animals, the biomass (number and weight of animals) and temperature of the animals (which is an indicator of the health of the animals) . The method is free of human contact or intervention with the animals, and in this sense is "remote". The information sensed by the sensing system is tabulated and conveyed to a human, eg. on a chart, printout or computer screen.

The thermographic image sensing system uses a thermographic camera which sends a video image to a digitizing board in a microcomputer. Software interprets the following features of the video image: number of animals in the area imaged; mass (estimated weight) of the animals; average skin temperature of each animal; approximate location of the animals in the imaged area; and the temperature of the surfaces adjoining the location of the animals. The software delivers the above information in a decipherable manner to those gathering information about the animals. Such information is relayed by diskette, wire or infrared transmission from the camera/ digitizing board combination to another computer that is operated by an "animal handler".

Under the present method, the thermographic screening of livestock before slaughter enables operators of the method to recognize animal health and quality problems while the animal is still alive and/or immediately after slaughter. Thermography detects changes in the body surface temperature as an indication of the metabolic state of the animal. Current non-thermographic methods obtain metabolic status information using invasive, labour dependant, time consuming techniques. The present method, sometimes referred to as "Remote Thermographic Animal

Sensing" or "RTAS", allows for automated screening of animals for example, on a farm, or in an abattoir.

Using RTAS, the following conditions are detectable: general body infections or infections to anatomical regions of an animal; injuries to, or bruising of an animal; metabolic disorders such as exhaustion or exertion (eg. Porcine Stress Syndrome (PSS) which can cause pork carcass quality problems such as P.S.E.- Pale Soft Exudative meat condition) . Other benefits of using RTAS include: labour savings to the slaughter and meat processing industries through an automated process for activities currently carried out manually and visually; improved selection and separation of animals having ideal metabolic status, thereby making the slaughter process more efficient and streamlined; identification of problem animals allows for useful interventions to occur while the animal is alive - eg. an exhausted animal may be rested, or an excited or nervous animal can be allowed to calm down and cool off, or an animal with PSS can be rested which is known to result in improved pork quality; identification of infected animals will allow for removal of those animals for a detailed inspection before slaughter occurs, thereby reducing the risk of disease in consumers, so there is an improvement in food safety and the inspection process is enhanced.

The thermographic sensing system used in the present method requires a thermographic imaging means, eg. camera, that can alone or with an adjunct, provide absolute or relative temperatures of objects in the field of view of the means. We selected a camera available through the company ISI Group Inc. of 211 Conchas S.E., Albuquerque, New Mexico, U.S.A., namely Model 9100, which operates under pyro-electric vidicon technology and produces a US Standard RS-170 output (30 frames per second) . Since this camera does not provide absolute temperatures, but rather only thermographic images, the images produced required

calibration to enable relative temperatures and ultimately absolute temperatures to be obtained. Our selected camera required very slight movement to produce a scanned image of the infrared scene.

The microcomputer for selection preferably has the following specifications: 486/33 , or faster, central processing unit; 200 Mb, or higher, hard disk; 10-20 Mb, or higher, ram; ISA bus architecture (due to the selected digitizing board's AT specifications). A digitizing board and software were used to capture and interconnect the imaging camera with the microcomputer and software programs. We selected a Matrox Model IP-8 digitizing board, supplied by Matrox Electronic Systems Ltd.of Dorval, Quebec, Canada, which provides a resolution of 512x512x8 bits, accepts RS-170 input, has a 2 Mb video frame buffer on the card, connects to an ISA bus, and has an extensive library of software development tools and demonstration programs for directly accessing the frame buffers.

Image analysis in the present method is a set of procedures for enhancing the visibility of objects in a scene, separating "objects of interest", ie. animals, from

"background", and performing measurements on the objects of interest and, optionally, the background. The scene sensed by the thermographic camera produces a signal which is conducted to a video-digitizer circuit board installed in the microcomputer. The board converts the signal into a square array of numbers inside the computer. The position of a number in the array corresponds to the position of one picture dot, or "pixel", in the scene. The value of the number indicates the pixel's "brightness".

The number of pixels in the array determines the resolution of the image. Usually the size of these arrays is 256-rows by 256-columns (more than 65,000 pixels) and may be as large as 1024-rows by 1024-columns (over one million pixels) . We used a 512 x 480 size of array in our

tests. The pixel values typically range from 0 to 255. The large size of the data array, combined with the intensive computations done on them, preferably requires computer hardware that can perform extremely fast and contain very large amounts of pixel data. Otherwise the time needed to extract information from a scene becomes excessive.

We used a pen with pigs to develop the present method and apparatus (see FIG.l). There is shown in Figure 1 a camera lens 1, start button 6, stop button 7, disc 2 for pen data output, disc 3 for parameter inputs, disc 4 for error trace data output, and report print-out 5. The thermographic camera was placed above the pen, pointing downwards, so that only the tops of pigs were visible to the camera. Data of interest for collection included the positions, sizes and temperatures of individual pigs. Computer algorithms for resolving these from the scene were developed and included adjusting for poor contrast between pigs and background, and compensating for overlapping images of pigs, eg. images formed from two or more pigs in substantial contact with each other.

Figure 4 illustrates a flowchart for software designed for use in our remote animal sensing technology. It will be apparent to any person skilled in the art that other software designs may also be used in accordance with the scope of the present invention, so references to the software in Figure 4 are non-limiting.

In one commercial application of the apparatus of the present invention the camera is designed to move mechanically from animal pen to animal pen. In another application the camera may remain stationary as animals move below and through the field of view. In either case, the first step in the image analysis is to obtain a video frame from the thermographic camera, wherein the frame includes animal images of animals within a predefined field

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of view. In our tests the frame was captured as a 512 x 480 pixel array. The array is then "cleaned" through an erode and dilate process. The array next undergoes a threshold process to define the animal profiles and separate them from the background "non-animal" areas. A row by row method utilizing a fixed formula may be used, as may a method of choosing the threshold by a dip in the histogram that is found at the transition between animal and background pixel values. In some cases further refinements in choosing the threshold value can come from a method of evaluating the image array and choosing the pixel value where the background begins to break up, thereby eliminating the background and not eroding any animal pixels. The final thresholding method may be any one of the above methods either alone or in combination, and is not limited to the described methods, in keeping with the scope of the present invention.

The thresholded image contains defined animal areas which are labelled and analyzed. Objects smaller than a predefined animal area are discarded; objects within an anticipated size are counted; and objects larger than the predetermined size are divided by the predefined size to estimate the number of animals in the large objects. The latter technique compensates for situations where the animals are so close together that the software perceives them as one animal. The parameter file which contains pen specific information is used to determine the predetermined animal size. The parameter file is initialized whenever the apparatus encounters the pen for the first time. The number of estimated animals is written to the output file, as is the estimation of the temperature of each animal based on the pixel values. The temperature may be in absolute form, ie. °C, if the camera is calibrated against an object of known temperature on a regular basis. A relative determination of the temperature may also be incorporated by noting which animals in each pen have an elevated temperature compared to their pen mates (see Table

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VII ) .

An average of the non-animal pixel values represents the background pen temperatures. These are written to the output file either in absolute or relative form.

The X and Y coordinates of the centre of each object will give the location of each animal and this information is then written to the output file.

The output file information is processed by a database management program to deliver information to the livestock operator in a useful manner. Inventory information can provide an estimate of the total animal inventory. Warning indicators can notify the livestock operator if significant changes in inventory are found. Animal weight data can be used to provide growth rate estimates for each pen of animals. Warning indicators can notify the operator if the animals are not growing at the optimal rates or if the animals are about to reach market weights. The disease incidence rate can be reported for each pen by noting the number of animals with elevated temperatures (fevers) , again warning indicators can alert the livestock operator of disease outbreaks and which pens are affected. The location and background information can be plotted in graphic form to allow the producer to view the locations of the animals and remotely view the temperature status of the pens. Warning indicators can draw the operator's attention to pens which are abnormally cold or hot.

Our work has also established a link between thermographic. remote sensing of pigs prior to slaughter and subsequent carcass meat quality. Carcass 24 hour pH and visual PSE meat score can be predicted from temperature data obtained under the present invention. With respect to pH, it is the ^' case that the pH of pork 24 hours after

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slaughter is a criterion of meat quality. We have found that animals with a large variation in pixel values are associated with an increased muscle pH (see Figure 5) . This relationship is strengthened when looking at pigs within on farm source. The significance of this finding is that commercial abattoirs may be able to sort loads of pigs on arrival into those that will give the highest quality pork.

The PSE condition of pork is a major quality flaw resulting in significant marketing losses. Thermographic sensing of pigs prior to slaughter has revealed a relationship between PSE pork and the thermographic pixel values (see Figure 6) . Pigs with higher pixel values tend to have an elevated PSE score, particularly when the score is greater than 2. Detecting PSE problems prior to slaughter can allow for quality selection when sorting live pigs and diverting PSE pigs to a rest facility where the pigs can rest and reduce the incidence of PSE pork.

In summary of some of the preferred aspects of one embodiment of the present invention, separating "pig" pixels into individual pigs involves scanning the image row-by-row starting from the top; when a pig profile is encountered, it is labelled with a unique identifier. Scanning continues until every pig profile has been filled with a unique identifier. Compensation for overlapping pig profiles is made. Once labelled, the unique identifiers and the pixels for each unique identifier may be used to determine one or more of the following:

Numbers: The unique identifiers yield an approximation of the number of pigs in the pen;

Weights: A count of the number of pixels in each unique identifier yields a measurement of the mass of the pig;

Positions: Calculating the center for each identifier yields where the pigs are positioned in the

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pen; Temperatures: Averaging the brightness of the pixels associated with each identifier yields a measure of the pig's body temperature. Pixel temperature can be used to predict actual carcass 24 hour pH and visual PSE meat score; and Background: Averaging the brightness of the pixels not associated with any identifier, ie. of the "non-pig" pixels, approximates the background

(pen) temperature.

There may be other useful kinds of information that can be obtained from the thermographic image data, as may occur to someone skilled in the art from consideration of the present description, so the above list is not intended to be limiting.

The following Tables I-III illustrate a Parameter

File layout and a sample Parameter File which have been developed for use in preferred software for carrying out the method and apparatus of the subject invention. y

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TABLE I

Parameter File Layout

DEFAULT

KEYWORD VALUE ACCEPTED VALUES

Barn-Name= blank one-line phrase to identify/describe the barn; used as a title on any printouts

Barn-ID= 'BARN' 4 character mnemonic uniquely identifying this barn location

Barn-Temp-MAX= 15 Range for 'background' barn

Barn-Temp-MIN= 10 temperatures

Species= Porcine Porcine, Bovine, etc...

Shipping-Weight= 102 target shipping weight (see Weight-Units)

Normal -Body- 39 normal average body

Temp= temperature (see Temp-Units)

Temp-Units= C units of measure for all TEMPERATURE measurements; C=celsius; F=fahrenheit; K=kelvin

Distance-Units= M units of measure for all DISTANCE measurements; R=screen rastor units; MM=mi Hi meters; CM=centimeters; M=meters; IN=inches; FT=feet; YD=yards

Weight -Units= KG units of measure for all WEIGHT measurements; GM=grams; KG=kilograms; OZ=ounces; LB=pounds

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DEFAULT

KEYWORD VALUE ACCEPTED VALUES

Lens= 18mm lens installed in camera

Output-Filename= Cymmddhh 8 character file name AND 3

• mm ¹ character file extension to identify the barn DATA file;

Printing= S D(etails only) S(ummaries only) or B(oth): indicates whether a printout is required; necessitates a printing device being correctly attached

Example "C2123123.59" where y= last digit of year eg.2 is 92; mm= month eg.12; dd= day eg.31; hh= hour eg.23; mm= minute eg.59

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TABLE II

Parameter File Layout

DEFAULT

KEYWORD VALUE ACCEPTED VALUES

Pen-Width= 20 width of the pen (see Distance-Units)

Pen-Length= 20 length of the pen (see Distance-Units)

Pen-Camera- 10 height of camera above the He ight= pen (see Distance-Units)

Pen-Avg-Weight average weight of an animal to be housed in this pen; used to 'separate' overlapping images when performing the inventory counting

Pen-MAX-Temp= Range for average animal Pen-MIN-Temp= body temperature in this pen

Pen-MAX-Weight= Range for average animal Pen-MIN-Weight= body weight in this pen

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DEFAULT

KEYWORD VALUE ACCEPTED VALUES Pen-ID= A(8) 8-characters of alpha- numerics labelling each pen in the order they are 'seen'; upon reading this parameter, the program pauses until 'signalled' ² to proceed;

'Signalled' during research and development means that the operator will 'Press Any Key to Continue'; however, for the final product, some form of "trip switch" will likely indicate that the camera is in the correct position above the pen and that the program should proceed with it's computations.

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TABLE III

Sample Parameter File

Barn-Name=Swineman, Joe

Barn-ID=JOES

Species=PORCINE

Shipping-Weight=85

Normal-Body-Temp=39

Temp-Units=C

Distance-Units=FT

Weight-Units=KG

Lens=18

Output-Filename=SWINEMAN.JOE

Printing=Y

Pen-Width=l7.5 Pen-Length=15.3 Pen-Camera-Height=12.3 Pen-ID=002

Pen-Width=14.4 Pen-Length=18.75 Pen-Camera-Height=12.3 Pen-ID=001

Pen-Width=15.25 Pen-Length=15.75 Pen-Camera-Height=14.75 Pen-ID=004

Pen-Width=18.8 Pen-Length=20.25 Pen-Camera-Height=14.75 Pen-ID=003

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Table IV below illustrates an output data file in ASCII text, one row per animal per pen, columnar data:

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TABLE IV

Col. Size Field Format Description

1 4 BarnID A(4)

2 8 PenNum A(8) D

9.9 ,0Z,LB o 8 5 AvgTemp 999.9 0-999.9 tvj

I O rπ 9 1 TempUnits A C,F,K

10 6 Xcenter. 9999.9 0-9999.9

11 6 Ycenter 9999.9 0-9999.9

12 2 CenterUnits AA R,MM,CM,M,IN,FT

13 5 OrientAng 999.9 0-360 DEGREES

58 + 12 70 bytes separators

Example Output DATA File

Col. 1 1 2 2 3 3 4 4 5 5 6 6 7

....5--.-O 5 0----5----0----5----0----5 0----5 0----5----0

HACD PEN4AB-2921203 1418001 0025.6 KG 038.9 C 0012.50007.2 FT 025.7 HACD PEN4AB-2921203 14180020023.2 KG 039.4 C 0002.30003.5 FT 215.3 O c HACD PEN4AB-2921203 14180030022.3 KG 037.2 C 0004.50002.4 FT 035.2

CD HACD PEN4AB-2921203 14180040024.4 KG 038.3 C 0013.70005.2 FT 145.4 CO

H HACD PEN4AB-2921203 14180050021.6 KG 039.1 C 0011.40006.3 FT 075.5

H c y

:..Orient Ang

-4 rπ .Center Units co .Y Center m I ;..X Center :..Temp Units .Avg Temp .Weight Units .Est Weight ..Anim Num •Time

.Date

Table V below illustrates Field Definitions developed for use in preferred software for use in carrying out the method and apparatus of the subject invention:

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TABLE V

Field Definitions

1. Barn ID . Barn Identification: 4-character mnemonic to identify the barn in which the following pens are located

Pen Num Pen Number: identification label assigned to uniquely identify each pen; obtained from Parameter File

3. Date Date: format YYMMDD; eg. 921203 is Dec. 3, 1992

4. Time Time of Day: 24-hour clock; format HHMM; eg. 2143 is 21 hours and 43 minutes (ie. 9:43pm)

5. Anim Num Animal Number: sequential number counting each labelled image; this is not an animal identification number but rather a sequential count of the numbers of animals in the pen

6. Est Weight Estimated Weight:

7. Weight Units Units for Estimated Weight: GM= grams, KG= kilograms, OZ= ounces, LB= pounds

8. Avg Temp Average Temperature:

9. Temp Units Units for Average Temperature: C= Celsius, F= Fahrenheit, K= Kelvin

10. X center . . X coordinate for Center of Gravity

11. Y center . Y coordinate for Center of Gravity

12. Center Units Units for Center of Gravity: same

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units for both X and Y coordinates; R= rastor, MM = m i l l i m e t e r s , CM= centimeters, M= meters, IN= inches, FT= feet 13. Orient Ang . . Angle of Orientation: units are

"degrees" of rotation from zero; zero is pointing to right of image screen

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Table VI below illustrates a typical Pen Details Report that may be printed at the end of each pen, ie. as an available report layout under operation of the preferred software. This "ticker tape" type of report would provide immediate feedback and information to the herdsman or farm manager, eg. while the unit is proceeding through a barn. The latter example anticipates that the camera would be on an overhead guide or track and could be selectively moved

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TABLE VI

Pen Details Report

Much like a "cash register" receipt, and printed at the end of each pen, this ticker tape report will provide immediate feedback and information to the herdsman or farm manager WHILE the unit is proceeding through the barn. O c

P E W D E T A I L S c Barn-Name: S ineman, Joe Species: PORCINE t

Lens: 18mm ** Shipping-Weight: 105KG m File: SWINEMAN.JOE * Normal-Body-Temp: 39C co

Xm Pen=PEN2AB-2 WxL= 17.5ft x 15.3ft

25 Animals: HiTemp=3, ShipWt=4

12-Mar-949:34pm Camera at 12.3ft H # Weight Temp. X-Location-Y Angle Temp Weight

001 25.6kg 38.9 C 12.5ft 7.2ft 25.7

002 23.2kg 39.4 C 2.3ft 3.5ft 215.3

024 24.4kg 38.3 C 13.7ft 5.2ft 145.4

025 21.6kg 39.1 C 11.4ft 6.3ft 75.5

Pen=PEN2AB-1 WxL= 14.4ft x 18.8ft

15 Animals: HiTemp=2, ShipWt=5

12-Mar-949:39pm Camera at 12.3ft H # Weight Temp. X-Location-Y Angle Temp Weight

001 85.6kg 38.9 C 12.5ft 7.2ft 25.7 W

002 73.2kg 39.4 C 2.3ft 3.5ft 215.3 T

014 84.4kg 38.3 C 13.7ft 5.2ft 145.4

015 81 .6kg 39.1 C 11 .4ft 6.3ft 75.5

Pen=PEN2AB-4 WxL= 15.3f t x 15.8ft

CO c 13 Animals: HiTemp=0, Sh ipWt=2

12-Har-949:44pm Camera at 14.8ft H

Ά ff Weight Temp. X-Location-Y Angle Temp Wei ht

001 95.6kg 38.9 C 12.5ft 7.2ft 25.7 W

C 002 83.2kg 38.4 C 2.3ft 3.5ft 215.3

H m o 012 84.4kg 38.3 C 13.7ft 5.2ft 145.4

X 013 81.6kg 39.1 C 11.4ft 6.3ft 75.5 m

21

Pen=PEN2AB-3 WxL= 18.8ft x 20.3ft

19 Animals: HiTcmp=1 , ShipWt=0

12-Mar-949:49pm Camera at 14.8ft H # Weight Temp. X-Location-Y Angle Temp Wei ht

001 35.6kg 38.9 C 12.5ft 7.2ft 25.7

Table VII below illustrates a Summary Report that may be printed at the end of the entire circuit of pens. The livestock manager can therefore be provided with a condensed, pen-based, inventory showing total numbers of pigs: in each pen; their temperatures; and, their weights for comparison to desired shipping weights for example.-

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TABLE VII

Summary Report

S U M M A R

Barn-Name: Swineman, Joe Species: PORCINE

Lens: 18mm ** Shipping-Weight: 105KG

File: SWINEMAN.JOE * Normal-Body-Temp: 39C

March 12 , 1993

# with # at Total#

Time Pen HiTemp ShipWt in Pen

9:34pm PEN2AB-2 3 4 25

9:39pm PEN2AB-1 2 5 15

9:44pm PEN2AB-4 0 2 13

9:49pm PEN2AB-3 1 0 19

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The preferable external interface for the processed data under the present method and apparatus is the data set of pen-based observations. This interface could also be achieved by a removable floppy diskette for transporting the data set(s) to a microcomputer for use in the database management program. It is also contemplated that the data set could be transmitted in other ways such as wireless modem or hardwired asynchronous communications line.

FIG. 2 indicates that estimating the weight of pigs under the present method has been achieved in our experiments. Plotting actual weight (scale weight - Y axis) vs pixel value (X axis) shows a strong, useful relationship exists. Although less data is available for correlating average pixel brightness to actual pig temperature, FIG. 3 does establish that a useful relationship exists between such data and that broad estimates of an animal's temperature can be measured remotely. Our tests also indicate that thermographic remote sensing appears to be able to predict pig carcass pH, as shown in Table VIII below and in Figure 5.

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TABLE VIII

Model fitting results for: Carcass pH

INDEPENDANT VARIABLE COEFFICIENT STD. ERROR T-VALUE SIG. LEVEL CONSTANT 5.340569 0.054929 97.22 0.0000

THERMOGRAPHIC VARIABLE 0.012696 0.005319 2.3872 0.0249 FARM VARIABLE 0.0026292 0.001159 2.3228 0.0286

R'SQ. (ADI)=0.2434 SE= 0.099753 MAE= 0.074226 DurbWat= 1.972 28 observations fitted; forecast(s) computed for 61 missing val. of dep. var. I Analysis of Variance for the Full Regression i

We have made studies of the possible financial benefits of the present method and apparatus to swine farming, which are summarized as follows: a. Reduced mortality rate: By allowing earlier diagnosis of diseases in a finishing barn, a reduction in mortality should result. Current average mortality is 3-4%. It should be possible to reduce this to a level of 1.5-2% by early diagnosis and treatment. This reduction of mortality rate will reduce the cost of production per pig of $2.00 to $2.50 per pig. For a 100 sow pig farm, this yields an annual saving of $4000-$5000. b. Fewer "poor growing" pigs: Improvements in health will improve growth rates on pig farms. It will also reduce the number of chronic "poor growing" pigs which impair overall growth on pig farms. By reducing the number of "poor growing" pigs, the "average days to market" number will drop. A modest improvement, such as 5 days less to market, will reduce costs by $2.50 per pig. c. Improved days-to-market: By being able to monitor growth accurately, producers will be able to identify weak areas in pig growth, and to correct them. A modest improvement in days-to-market on average farms (5 days) will reduce cost a further $2.00-$2.50 per pig. d. Less time looking for market-weight pigs: T h e concept of being able to monitor pig growth will allow farmers to identify pigs that are market weight. This will reduce the amount of time spent looking for market weight pigs. On a 100 sow farm, two hours per week could be saved, which would translate into a $1000 saving per year (or $1.00 per pig).

It will be obvious to one skilled in the art that modifications to the specific examples used for illustration may be made without departing from the spirit and scope of this invention.

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