Patent Application
20220254155
The present invention relates to a method and a treatment device for plantation treatment of a plantation field, as well as a controlling device for such a treatment device.
The general background of this invention is the treatment of plantation in an agricultural field. The treatment of plantation, in particular the actual crops, also comprises the treatment of weed in the agricultural field, the treatment of the insects in the agricultural field as well as the treatment of pathogens in the agricultural field.
Agricultural machines or automated treatment devices, like smart sprayers, treat the weed, the insects and/or the pathogens in the agricultural field based on ecological and economical rules. In order to automatically detect and identify the different objects to be treated image recognition is used.
However, agricultural machines operate in very heterogeneous conditions. This includes illumination, but also phenotypical appearances of crops, weeds, insects and pathogens in the agricultural field. This depends on different genotypes, plasticity of the weeds to different environmental conditions and differences in the host plantations for pathogens (i.e. different defense mechanisms, different color of the variety) or different canopy structures after weather events (wind, rain, washing of the cuticula, damaging leaves). All this is a challenge for image recognition algorithms, in particular if a real time decision is needed on a machinery taking images and making application decisions, like treating the plantation by triggering a spraying nozzle, at the same time.
It would be advantageous to have an improved method for plantation treatment based on image recognition.
The object of the present invention is solved with the subject matter of the independent claims, wherein further embodiments are incorporated in the dependent claims. It should be noted that the following described aspects and examples of the invention apply also for the method, the treatment device and the controlling device.
According to a first aspect, the method for plantation treatment of a plantation field comprises:
According to a further variant of the first aspect, the method for plantation treatment of a plantation field comprises:
According to a further variant of the first aspect, the method for plantation treatment of a plantation field comprises:
According to an exemplary embodiment controlling a treatment arrangement of a treatment device based on the first image recognition analysis with improved parametrization (step 8) can be conducted after a certain time period (TP) after controlling a treatment arrangement of a treatment device based on the first image recognition analysis with the stored (initial) parametrization (step 7) has started. The time period (TP) may be:
According to an exemplary embodiment controlling a treatment arrangement of a treatment device based on the first image recognition analysis with improved parametrization is conducted after a certain time period after controlling a treatment arrangement of a treatment device based on the first image recognition analysis with the stored parametrization has started.
According to an exemplary embodiment the time period is selected from a group, the group consisting of 0 to 100 seconds, 0 to 100 minutes, 0 to 100 hours, 0 to 10 days, 0 to 10 weeks, and 0 to 12 months.
Recognizing, as used herein, comprises the state of detecting an object, in other words knowing that at a certain location is an object but not what the object exactly is, and the state of identifying an object, in other words knowing the exact type of object that has been detected.
An unsatisfying image analysis result, as used herein, can be understood as a result of an image recognition analysis, in which the result does not meet predetermined criteria. Preferably, such an unsatisfying result comprises that an image analysis results in a negative or an uncertain result. An uncertain result preferably comprises that the image recognition analysis detects an item on the image, but cannot identify the item. Further preferably, an uncertain result preferably comprises that an image recognition analysis is uncertain, if the identification made is correct. An uncertain result may for example be an identification which allows the determination of a weed group, but not a weed species. With this respect, the first image recognition with the initially stored parametrization may reveal the weed group, but not the weed species, whereas the second image recognition with the updated parametrization may reveal not only the weed group, but also the weed species. The weed group may be any weed classification which is on a higher level than the weed species. The weed group may be for example a weed family (e.g. the family Poaceae), a weed tribe (e.g. one of the tribes Aveneae, Bromeae, Paniceae and Poeae), or a weed genus (e.g. Alopecurus) in the biological sense. The weed species is the species of the weed in the biological sense (e.g. Alopecurus myosuroides=black-grass).
Ambient information or data, as used herein, can be understood as all additional data of the field situation and/or the surroundings of the plantation field. It may include historical data of the field or permanent properties of the field, like soil composition. It may also include statistical weather data for the location of the plantation field.
The improved parametrization directly improves first image recognition analysis but also improves the self learning capabilities of the machine learning algorithm providing the respective parametrization for the first image recognition analysis.
Thus, the first image recognition analysis iteratively or gradually becomes more resistant to external factors like weather, illumination and/or damage of the plantation. Furthermore, in field image recognition performed on the fly can be improved, whenever uncertainties in the image recognition arise. Such improvement increases detection accuracy and hence reduces the amount of herbicides, insecticides and/or fungicides needed for cultivating the crop and maximizing yield. Therefore, the environment can be relieved and costs can be reduced.
The improved parametrization preferably is fed back for the first image recognition analysis as fast as possible. In realistic conditions, the timeframe for this is about several minutes. This procedure would be the case for embedded telematics. Additionally, the improved parametrization can also be fed back time delayed, for example for the start of the new farming season. In this case the improved parametrization would be provided as an annual service. In any case, the machine learning algorithm can only be improved when being provided with the improved parametrization.
The plantation treatment preferably comprises protecting a crop, which is the cultivated plantation on the plantation field, destroying a weed that is not cultivated and may be harmful for the crop, in particular with a herbicide, controlling the insects on the crop and/or the weed, in particular with an insecticide, and controlling any pathogen like a disease, in particular with a fungicide.
The treatment arrangement, as used herein, or also called control technology, preferably comprises chemical, mechanical and/or electric control technology. Chemical control technology preferably comprises at least one means, particularly a spray gun, for application of insecticides and/or herbicides. Mechanical control technology preferably comprises means for sucking, pulling and/or stamping plants and/or insects. Electric control technology comprises applying electric field or current flow, e.g. as provided by Zasso, and/or radiation, particularly laser, based means for controlling plants and/or insects.
The treatment arrangement is controlled based on the first image recognition analysis. In other words, based on the first image recognition analysis it is decided if a plantation, insect and/or pathogen survives or is destroyed. For instance, when the first image recognition analysis identifies a weed that is harmful to the cultivated crop on the plantation field, the treatment arrangement is configured to destroy the weed in order to protect the crop. For instance, when the first image recognition analysis identifies an insect that is harmful to the cultivated crop on the plantation field, the treatment arrangement is configured to eliminate the insect in order to protect the crop.
The machine learning algorithm may comprise decision trees, naive bayes classifications, nearest neighbors, neural networks, convolutional or recurrent neural networks, generative adversarial networks, support vector machines, linear regression, logistic regression, random forest and/or gradient boosting algorithms.
Preferably, the machine learning algorithm is organized to process an input having a high dimensionality into an output of a much lower dimensionality. Such a machine learning algorithm is termed “intelligent” because it is capable of being “trained.” The algorithm may be trained using records of training data. A record of training data comprises training input data and corresponding training output data. The training output data of a record of training data is the result that is expected to be produced by the machine learning algorithm when being given the training input data of the same record of training data as input. The deviation between this expected result and the actual result produced by the algorithm is observed and rated by means of a “loss function”. This loss function is used as a feedback for adjusting the parameters of the internal processing chain of the machine learning algorithm. For example, the parameters may be adjusted with the optimization goal of minimizing the values of the loss function that result when all training input data is fed into the machine learning algorithm and the outcome is compared with the corresponding training output data. The result of this training is that given a relatively small number of records of training data as “ground truth”, the machine learning algorithm is enabled to perform its job well for a number of records of input data that higher by many orders of magnitude.
Preferably, the steps of recognizing items on the taken image by running a second image recognition analysis of a second complexity on the image based on the ambient data on an external device, wherein the second complexity is higher than the first complexity and determining an improved parametrization based on the second image recognition analysis for the machine learning algorithm for improving the first image recognition analysis are executed by an external server, in particular a cloud server. The complexity may be higher when having for example the option to distinguish different species of weed. The complexity may be lower when having for example only the option to distinguish weeds from beneficial plants. The complexity can be reduced by for example reducing the nodes in a model to make the computational procedure faster. Further preferably, the steps of taking an image of a plantation of a plantation field, recognizing items on the taken image by running a first image recognition analysis of a first complexity on the taken image based on a stored parametrization of a machine learning algorithm, identifying an unsatisfying image analysis result and controlling a treatment arrangement of a treatment device based on the first image recognition analysis are executed by an embedded software, in particular by an embedded software on an agricultural machine.
In a preferred embodiment, the ambient data comprises a type of a field crop and/or a growth stage of the field crop and/or illumination characteristics and/or weather conditions.
In one embodiment, the weather condition, preferably in form of current weather data, is recorded on the fly and/or on the spot. Such current weather data may be generated by different types of weather sensors mounted on the treatment device and/or one or more weather station(s) placed in or near the field. Hence, the current weather data may be measured during movement of the treatment device on the plantation field. Current weather data refers to data that reflects the weather conditions at the location in the plantation field a treatment decision is to be made. Weather sensors are for instance rain, UV or wind sensors.
The type of field crop of the ambient data preferably is not a real time data but does relate to a general information about the plantation field, in particular the type of crop that this specific plantation field is used for cultivating. Thus, it is known which type of crop should generally be identified by the image recognition analysis.
The growth stage of the field crop is known from the time of seeding when cultivating the plantation field. Therefore, an expected growth stage of the field crops can be determined.
The illumination characteristics preferably comprise information about the current time and current the angle of the sun to the illuminated plantation field.
The weather conditions preferably comprise the current weather as well as consequences thereof, in particular fog and/or humidity.
Preferably, the ambient data is at least partially provided by an external service provider.
The ambient data preferably can be used as sources for unexpected image information detected by the image recognition analysis. For example, reflections from water on the plantation can be deducted or unexpected colors of the plantation based on unusual illumination can be adjusted in order to improve the image recognition.
Preferably, the machine learning algorithm is trained on the basis of a plurality of images, in particular images containing imagery of at least one type of crop, weed, insect and/or pathogen.
In a preferred embodiment, the unsatisfying image analysis result is indicated by a low confidence of the machine learning algorithm.
A low confidence case comprises the first image recognition analysis based on the stored parametrization of the machine learning algorithm being uncertain, if an object to be identified is present at all or that an object is detected and therefore present but cannot be identified. The confidence may be defined as the probability that a particular weed e.g. belongs to a specific species. For example, a confidence level of 60% means that the system delivers a result with a probability of 0.6 that the corresponding weed belongs to a specific species/ . . . /category.
The confidence level can be adjusted according to the use case and/or according to the type of treatment. Preferably, the confidence level is below 90%, more preferably below 80%, most preferably below 70%, particularly preferably below 60%, particularly more preferably below 50%, particularly most preferably below 40%, for example preferably below 30%, for example more preferably below 20%, for example most preferably below 10%.
For example, a confidence level of 60% means that the system delivers a result with a probability of 0.6 that the corresponding weed belongs to a specific species/ . . . /category.
More details on the confidence level can be found on: https://en.wikipedia.org/wiki/Artificial_neural_network#Generalization_and_statistics
In a preferred embodiment, the method comprises buffering the image and/or the ambient data before running the second image recognition analysis.
The second image recognition analysis is based on the image, in particular all the raw image data of the taken image, and the ambient data. However, the second image recognition analysis does not have to be provided with the information in real-time. The current image and ambient data are preferably stored or buffered as a snapshot of the current situation. The stored data then can be provided to the external device at any given time.
In a preferred embodiment, the buffered image and/or buffered ambient data are transmitted to the external device, preferably an internet server, based on the availability of a transmission technology, in particular a cell phone coverage, an idle service and/or a WLAN connection.
In a preferred embodiment, the transmission of the buffered image and buffered ambient data to the external device is delayed as long as there is no transmission technology available. Preferably, the transmission to the external device is triggered by a trigger signal. The trigger signal is preferably based on a re-availability of a transmission technology. In other words, when the transmission technology is available again, a trigger signal is generated, triggering the transmission of the buffered image and buffered ambient data to the external device. Alternatively, the trigger signal is queued, until the transmission technology is available again.
Alternatively, the trigger signal is also based on a predetermined condition, for example a predetermined time frame for buffering and transmitting and/or a predetermined amount of buffered data, before transmitting the buffered data to the external device. In other words, the trigger signal is only generated, when a predetermined time and/or amount of buffering data has been executed.
The trigger signal is preferably either generated in the control device or generated externally and provided to the control device via a communication technology interface, further preferably providing the trigger signal to the buffer interface.
Cultivated plantation fields are often not supplied by a transmission technology that has offers enough throughput to transmit the taken image and the ambient data to the external device.
Therefore, the image and the ambient data are preferably buffered and preferably collected before being transmitted to the external device. If the transmission technology however is stable and powerful enough and no collecting of several unsatisfying image analysis result is required, the image and the ambient data can be directly transmitted to the external device without buffering.
In a preferred embodiment, the second image recognition analysis is trained based on additional data sources, preferably smart phone apps and/or drone imagery, wherein preferably the additional data sources provide geographical information and/or expected phenotypical differences between regions.
Preferably, the second image recognition analysis is based on a parametrized model, wherein the parametrized model is based on and/or trained with additional data sources.
Preferably, the second image recognition analysis considers a parametrization of a higher complexity than that of the first image recognition analysis, which results from e.g. a larger number of parameters to be considered for an algorithm. This requires more computational power than the first image recognition analysis. Preferably, the second image recognition analysis of a second complexity has a higher complexity than the first image recognition analysis of a first complexity as far as the second image recognition analysis requires more computational power than the first image recognition analysis .
Preferably, the additional data sources at least partially comprise an external service provider.
The second image recognition analysis it not only technically more complex than the first image recognition analysis, but preferably also is provided with more diverse input data at the training stage. Thus, the second image recognition analysis is able to formulate additional predictions in order to recognize objects on the provided image. For example, the external device is provided with expected phenotypical differences between regions. Thus, the same type of crop may have a different appearance depending on the region it is cultivated. Therefore, the second image recognition analysis can consider this difference and improve the recognition analysis and identify an object as a cultivated crop that the first image recognition analysis could only detect but not identify.
In a preferred embodiment, the second image recognition analysis is based on a neural network, in particular a neural network with more layers and/or more nodes than the neural network of the first image recognition algorithm and/or different more complex algorithms for background segmentation than the first image recognition analysis.
Preferably, the first image recognition analysis is based on a compressed neural network. The compressed neural network is based on a model, which only includes essential nodes for decision-making. The essential nodes relate to nodes, which pass a predetermined threshold for activating the node during the training of the model. The lower number of nodes lead to a lower complexity.
The model complexity can be considered as a counting of the total amount of learnable parameters. Specifically, a measure for the model complexity may be the parameter file in terms of MB for the considered models. This information may be useful for understanding the minimum amount of GPU memory required for each model.
A total memory consumption may include all the memory that is allocated, i.e. the memory allocated for the network model and the memory required while processing a batch.
A computational complexity may be defined as a measure of the computational cost of each DNN model considered using the floating-point operations (FLOPs) in a number of multiply-adds. More in detail, multiply-adds are counted as two FLOPs because, in many recent models, convolutions are bias-free and it makes sense to count multiply and add as separate FLOPs.
Inference time per image may be measured in terms of milliseconds.
Details can be taken from IEEE Access, vol 4/2018: “Benchmark Analysis of Representative Deep Neural Network Architectures” of Simone Bianco, Remi Cadene, Luigi Celona and Paolo Napoletano, DOI: 10.1109/ACCESS.2018.2877890.
According to an embodiment of the invention, the complexity in the meaning of the invention includes the above referenced model complexity. According to an embodiment of the invention, the complexity in the meaning of the invention includes the above referenced total memory consumption. According to an embodiment of the invention, the complexity in the meaning of the invention includes the above referenced computational complexity. According to an embodiment of the invention, the complexity in the meaning of the invention includes the above referenced inference time per image. According to an embodiment of the invention, the complexity in the meaning of the invention includes at least two of the above referenced aspects of the model complexity, the total memory consumption, the computational complexity and inference time per image. According to an embodiment of the invention, the complexity in the meaning of the invention includes the model complexity, the total memory consumption, the computational complexity and inference time per image.
In a preferred embodiment, the neural network of the first image recognition algorithm is based on the neural network of the second image recognition algorithm. Further preferred, the neural network of the first image recognition algorithm is a compressed version of the neural network of the second image recognition algorithm. This may be achieved by elimination of nodes in the layer(s) of the neural network of the second image recognition algorithm, which leads to a lower complexity.
Preferably, the external device has more computational power than the device used on the plantation field for running the first image recognition analysis. Further preferred the external device is configured to compress the neural network of the second image recognition algorithm. The external device may be a central computation unit CCU. The CCU may be positioned on the farming machine, but separate from a control loop processing the first image recognition. The data transfer may be conducted by a wired connection. The CCU may also be positioned on site, e.g. beside an agricultural field. In this case the data transmission may be conducted by radio transmission. The CCU may also be positioned remote on a farmer's head quarter (farm). In this case the data transmission can be conducted by radio transmission from the field or by transferring/exchanging data when returning from the field, either by wire or wireless. The CCU may also be positioned elsewhere in the world. In this case the data transmission may be conducted by any LAN or Wifi connection, either from the field or from an access point when returning from the field. The delay between requesting for an updated parametrization and applying the updated parametrization may depend on the expected response time and the access to the CCU. In case the CCU is on the farming machine, the response time may be short, i.e. within seconds or shorter. In case the CCU is remote, e.g. elsewhere in the world, and the internet access is bad for the farming machine, the response time may be some days, even weeks, so that updated parametrization may be applied e.g. weeks or months later, even in the following season.
According to a second aspect a controlling device for a treatment device for plantation treatment of a plantation of a plantation field, comprises an image interface being adapted for receiving an image of a plantation of a plantation field, a treatment control interface, an image recognition unit being adapted for recognizing items on the taken image by running a first image recognition analysis of a first complexity on the image based on a stored parametrization of a machine learning algorithm. The image recognition unit is adapted for identifying an unsatisfying image analysis result. The image recognition unit is adapted for determining ambient data corresponding to the taken image. The treatment device comprises a communication interface being adapted for transmitting the taken image and the determined ambient data to an external device being adapted for recognizing items on the taken on the image based on the ambient data, wherein the second complexity is higher than the first complexity. The communication interface is adapted for receiving an improved parametrization for the first machine learning algorithm for improving the first image recognition analysis from the external device. The treatment device comprises a controlling unit being adapted for generating a treatment controlling signal for a treatment arrangement of a treatment device based on the improved first image recognition analysis. The controlling unit is adapted for outputting the treatment controlling signal to the treatment control interface.
Preferably, the ambient data is provided to the image recognition unit from a further external unit and/or a further internal unit like a data storage.
In a preferred embodiment, the controlling device comprises a machine learning unit, being adapted for indicating an unsatisfying image analysis result by a low confidence of the machine learning algorithm.
In a preferred embodiment, the controlling device comprises a buffer interface, being configured for transmitting to and receiving from a buffer the image and the ambient data before them being transmitted to the external device.
In a preferred embodiment, the communication interface is adapted for transmitting the buffered image and buffered ambient data to the external device based on the availability of a transmission technology, in particular a cell phone coverage, an idle service and/or a WLAN connection.
In a preferred embodiment, the second image recognition analysis is run based on additional data sources, preferably smart phone apps and/or drone imagery, wherein preferably the additional data sources provide geographical information and/or expected phenotypical differences between regions.
According to a third aspect a treatment device for plantation treatment of a plantation of a plantation field comprises an image capture device being adapted for taking an image of a plant field, a treatment arrangement, an image interface being adapted for providing an image captured by the image capture device to a controlling device, as described herein, a treatment control interface being adapted for receiving a treatment controlling signal from a controlling device, as described herein. The image interface of the treatment device is connectable to an image interface of a controlling device, as described herein. The treatment control interface of the treatment device is connectable to a treatment control interface of a controlling device, as described herein. The treatment device is adapted to activate the treatment arrangement based on the treatment controlling signal received from the controlling device, as described herein, via the treatment control interface of the treatment device.
In an example, an inertial navigation unit is used alone, or in combination with a GPS unit, to determine the location, such as the location of the image capture device when specific images were acquired. Thus for example, the inertial navigation unit, comprising for example one or more laser gyroscopes, is calibrated or zeroed at a known location (such as a docking or charging station) and as it moves with the at least one camera the movement away from that known location in x, y, and z coordinates can be determined, from which the location of the at least one camera when images were acquired can be determined.
Thus, imagery can be acquired by one platform that could analyze it to detect plantation and determine which objects are to be treated, and the locations of the objects to be treated determined. For example, a UAV (unmanned aerial vehicle) can fly around a plantation field or a robotic land vehicle moves around the plantation field and acquires and analyses the imagery. Then, the information of the locations of the objects can be used by a second platform, for example a robotic land vehicle that goes to the locations of the objects and controls them, for example by applying a chemical spray at that location or mechanically extracting a weed - for example.
In a preferred embodiment, the image capture device comprises one or a plurality of cameras, in particular on a boom of the treatment device, wherein the image recognition unit is adapted for recognizing insects, plantation, in particular crops and/or weeds, and/or pathogens using red-green-blue RGB data and/or near infrared NIR data.
In a preferred embodiment, a treatment device, as described herein, further comprises a controlling device, as described herein.
In a preferred embodiment, a treatment device, as described herein, is designed as a smart sprayer, wherein the treatment arrangement is a nozzle arrangement.
The nozzle arrangement preferably comprises several independent nozzles, which may be controlled independently.
Advantageously, the benefits provided by any of the above aspects equally apply to all of the other aspects and vice versa. The above aspects and examples will become apparent from and be elucidated with reference to the embodiments described hereinafter.
Exemplary embodiments will be described in the following with reference to the following drawings:
Step 10 comprises taking an image 10 of a plantation of a plantation field 300.
In step 20 a first image recognition analysis of a first complexity is run on the taken image 10. The first image recognition analysis has a first complexity and is based on a stored parametrization P of a machine learning algorithm. The machines learning algorithm preferably is an artificial neural network. Thus, items 20 on the taken image 10 are recognized, at least detected and ideally identified.
In step 30, it is checked, if the first image recognition analysis provides a satisfying image analysis result R. If an item, which corresponds to an object like a crop, weed, insect or pathogen is detected but cannot be identified, the image analysis result R is unsatisfying. If the image analysis result R is satisfying, the method jumps to step 70 and the first image recognition analysis is complete and a treatment arrangement 270 of a treatment device 200 is treated based on the first image recognition analysis. If the image analysis result R is unsatisfying, the method jumps to step S40. However, the treatment arrangement 270 of the treatment device 200 is still treated based on the first recognition analysis regarding the detected and identified items 20 anyways. The not identified objects are not treated. Alternatively, the treatment arrangement 270 of the treatment device 200 is provided with a supplied map, indicating how the field has been treated in the past, and treats the plantation in the field based on the supplied map. Alternatively, no plantation is treated at all, if the image analysis result R is unsatisfying. This is the safest variation in view of potential environmental and/or economical risk.
In step S40, in addition to the image 10, ambient data 21 corresponding to the taken image 10 is determined. The ambient data 21 preferably comprises the type of crop, the growth stage of the plantation and/or illumination characteristics. All this information determining the ambient data 21 is a snapshot of the time, the image 10 was taken. The method jumps to step S50.
In step S50, a second image recognition analysis of a second complexity is run on the taken image 10 and the ambient data 21. The second complexity of the second image recognition analysis is higher than the first complexity of the first image recognition analysis. Normally, the capabilities of a device running the first image recognition analysis on a plantation field 300 are limited. Therefore, the second image recognition analysis is run on an external device 400. The second image recognition analysis is used to recognize and identify items 20 on the image 10. The second image recognition analysis is thereby run by a further machine learning algorithm. The method jumps to step S60.
In step S60, the further machine learning algorithm determines an improved parametrization PI based on the second image recognition analysis. The improved parametrization PI is then used to improve the first image recognition analysis and used to train the machine learning algorithm providing the parametrization P to the first image recognition analysis in an improved way. The method then jumps to step 20. Ideally, the first image recognition analysis was improved in such a way that it results in a satisfying image analysis result the next time such a situation occurs.
A treatment device 200, preferably a smart sprayer, comprises an image capture device 220 and a treatment arrangement 270 as well as an image interface 210 and a treatment control interface 230.
The image capture device 220 comprises at least one camera, configured to take an image 10 of a plantation field 300. The taken image 10 is provided to an image interface 210 of the treatment device 200. The image interface 210 transmits the image 10 to a controlling device 100, in particular an image interface 110 of the controlling device 100.
The controlling device 100 comprises an image recognition unit 120, a machine learning unit 160 and a controlling unit 170. Additionally, the controlling device 100 comprises an image interface 110, a treatment control interface 130, a communication interface 150 and a buffer interface 180. The controlling device 100 may refer to a data processing element such as a microprocessor, microcontroller, field programmable gate array (FPGA), central processing unit (CPU), digital signal processor (DSP) capable of receiving field data, e.g. via a universal service bus (USB), a physical cable, Bluetooth, or another form of data connection. The controlling device 100 may be provided for each treatment device 200. Alternatively, the controlling device may be a central controlling device, e.g. a personal computer (PC), for controlling multiple treatment devices 200 in the field 300.
The image interface 110 receives the image 10 from the image interface 210 of the treatment device 200 and provides the image 10 to the image recognition unit 120. The image recognition unit 120 runs a first image recognition analysis based on parameters P, which are provided by the machine learning unit 160. Here the machine learning unit 160 may include trained machine learning algorithm(s), wherein the output of the machine learning algorithm(s) may be used for the image recognition. Based on the first image recognition analysis, the image recognition unit 120 determines image analysis results R. The image analysis results R, for example the recognized and identified items 20 of the analyzed image 10, are provided to the controlling unit 170. The controlling unit 170 determines a treatment controlling signal S based on the image analysis results R. For example, when the image analysis results R contain an identified weed that is harmful for the crop and has to be treated, in particular destroyed, the controlling unit 170 determines a treatment controlling signal S that instructs the treatment arrangement 270 to treat the identified weed. In this case, the treatment arrangement 270 comprising a nozzle arrangement of several independent nozzles is instructed to aim for the identified weed and the treatment arrangement 270 sprays the weed with a herbicide through the aiming nozzle. This however, can only be done for items 20, which are detected by the image recognition unit 120 and additionally identified by the image recognition unit 120. If an item 20 is detected, in other words, the image recognition unit 120 is certain that an object has been found, but the item 20 cannot be identified, the controlling unit 170 cannot determine a fitting treatment controlling signal S for this object, since it is not clear if it is a crop or a weed, or which type of insect or which type of pathogen was detected. The image recognition units 120 thus determines that the image analysis results R are unsatisfying.
In the case of an unsatisfying analysis result R, the image recognition unit 120 provides the image 10, in particular the raw data from the image capture device 220, and additionally ambient data 21 like the type of field crop, the growth stage and/or illumination characteristics, to an external device 400 via a communication interface 150 of the controlling device 100 and a communication interface 450 of the external device 400. The external device 400 preferably is an internet server.
The image 10 and the ambient data 21 are provided to an image recognition unit 420, which runs a second image recognition analysis, which is more complex than the first image recognition analysis. More complex in this case refers to more deep layers and/or different algorithms for background segmentation. In addition to the higher complexity, the second image recognition analysis is provided by additional data from additional data sources. For example, geographical information and/or expected phenotypical differences between regions can be provided by smart phone apps and/or drone imagery. The second image recognition analysis is also based on an improved parametrization PI of a machine learning algorithm of a machine learning unit 460, which based on the higher amount of input data and better quality of image recognition analysis has improved training and learning characteristics. Here the machine learning unit 460 may include trained machine learning algorithm(s), wherein the output of the machine learning algorithm(s) may be used for the improved image recognition. Therefore, the external device 400 can provide an improved parametrization PI from the machine learning unit 460 via the communication interface 450 of the external device 400 and the communication device 150 of the controlling device 100 to the machine learning unit 160 of the controlling device 100.
Based on the improved parametrization PI, the machine learning unit 160 can train and learn the machine learning algorithm in an improved way. Therefore, the provided parametrization P to the image recognition unit 120 improves the first image recognition analysis and reduce the cases of an unsatisfying image analysis result R.
The above method will be described along an exemplary embodiment as follows: For the image recognition a smart sprayer may be equipped with 10 or more cameras. The cameras may have a reaction or response time of less than 100 milliseconds and may record up to 20 and more images per second. As there is a closed control loop on the camera and the system, the sprayer is activated at almost the same moment. Image recognition with high accuracy requires large computing capacities. However, it may be expensive to install e.g. a super powerful processor for several hundred EUR/processor on each camera, so that this can be compensated by the approach of this invention. It may take about 50 to 150 milliseconds from the image acquisition of the camera to the nozzle control, i.e. after about 50 to 150 milliseconds a nozzle control must already be performed after the first image analysis. A smart sprayer drives over the plantation field and sometimes it does not recognize certain weeds, single images are sent to an external server (via e.g. LTE/5G), images are then sent to the CCU (i.e. central computing unit/central processing unit, also referred to as master unit). With the camera including the computational resources on site, for example, only 4-5 weeds (or weed classes) can be distinguished from each other. The data base however can distinguish 110 weeds. However, this requires computational power and in particular an efficient and adapted image recognition with an improved parametrization. This will be provided by an external device to which the image data are transferred for computing the updated parametrization.
However, there might be cases when it is not wanted or not possible to transmit the image 10 and/or the ambient data 21 directly to the external device 400. For example, different snapshots of images 10 and ambient data 21 should be collected before providing them to the external device 400. In another example, the external device 400 just cannot be reached by the communication interface 150 when the controlling device 100 has no access to any communication means, like WLAN or mobile data like LTE, 5G. In such cases, the image 10 and the ambient data 21 are transmitted to a buffer interface 180. The buffer interface 180 transmits the image 10 and the ambient data 21 to a buffer interface 81 of a buffer 80. The buffer 80 can be any kind of storage device, as long as it is suitable to store the received data for as long as it is needed to be stored it. When the buffered data is needed again, the buffer 80 will transmit the image 10 and the ambient data 21 back to the controlling device 100 via the buffer interface 81 of the buffer 80 and the buffer interface 180 of the controlling device 100. The image 10 and the ambient data 21 are then directly transmitted from the buffer interface 180 of the controlling device 100 via the communication interface 150 of the controlling device 100 to the communication interface 450 of the external device 400 for the second image recognition analysis. Preferably, the buffer interface 180 is provided with a trigger signal (not shown), indicating, if a transmission technology is available. Only if the trigger signal is present, the image 10 and the ambient data 21 and/or data buffered in the buffer 80 will be transmitted to the communication interface 450 of the external device 400 via the communication interface 150 of the controlling device 100. If the trigger signal is not present, the image 10 and the ambient data 21 will be transmitted to the buffer interface 81 of the buffer 80.
There may be different situations with respect to the access to the external device, i.e. the CCU (central computing unit or Connectivity Control Unit). Depending on the country a different use case is important. In some cases mobile internet is available in the field, then the time intervals between the first image analysis and the second image analysis are short (a few seconds, maximum a few minutes), while the farming machine is driving, the nozzle control can be adjusted after only a few meters (e.g. 5 or 10 meters), already by means of the “parametrization” of the second image analysis, which is used to update the parametrization of the first image recognition. In other cases there is no mobile internet available in the field, however, a CCU is installed on the farming machine, which can carry out the arithmetic operations for the second image analysis, then the time intervals between the first image analysis and the second image analysis are also short (a few seconds). While the tractor is driving, after only a few meters (e.g. 5 or 10 meters) the nozzle control can already be adapted by means of the “parametrization” of the second image analysis. In yet another cases, there is neither mobile internet available in the field, nor is a CCU installed on the farming machine, so that the second image analysis can only be carried out after the entire crop protection application has been completed. The time intervals between the first image analysis and the second image analysis can then be several hours. The time intervals between the above first image analysis, approximately 80 milliseconds after image acquisition, and the second image analysis can then be several hours and the adapted nozzle control by means of the “parametrization” of the second image analysis can be much longer, because the nozzle control is only adapted the next time “driving onto the field”, this can be weeks, months or one season later.
The UAV 200 has an image capture device 220 comprising one or a plurality of cameras, and as it flies over the plantation field 300 imagery is acquired. The UAV 200 also has a GPS and inertial navigation system, which enables both the position of the UAV 200 to be determined and the orientation of the camera 220 also to be determined. From this information, the footprint of an image on the ground can be determined, such that particular parts in that image, such as the example of the type of crop, weed, insect and/or pathogen can be located with respect to absolute geospatial coordinates. The image data acquired by the image capture device 220 is transferred to an image recognition unit 120.
The image acquired by the image capture device 220 is at a resolution that enables one type of crop to be differentiated from another type of crop, and at a resolution that enables one type of weed to be differentiated from another type of weed, and at a resolution that enables not only insects to be detected but enables one type of insect to be differentiated from another type of insect, and at a resolution that enables one type of pathogen to be differentiated from another type of pathogen.
The image recognition unit 120 may be external from the UAV 200, but the UAV 200 itself may have the necessary processing power to detect and identify crops, weeds, insects and/or pathogens. The image recognition unit 120 processes the images, using a machine learning algorithm for example based on an artificial neural network that has been trained on numerous image examples of different types of crops, weeds, insects and/pathogens, to determine which object is present and also to determine the type of object.
The UAV also has a treatment arrangement 270, in particular a chemical spot spray gun with different nozzles, which enables it to spray an herbicide, insecticide and/or fungicide with high precision.
As shown in
10 image
20 (recognized) item on image
21 ambient data
80 buffer
81 buffer interface
100 controlling device
110 image interface
120 image recognition unit
130 treatment control interface
150 communication interface
160 machine learning unit
170 controlling unit
180 buffer interface
200 treatment device, smart sprayer, UAV
210 image interface
220 image capture device
230 treatment control interface
270 treatment arrangement
300 plantation field
400 external device
420 image recognition unit
450 communication interface
460 machine learning unit
510 crop
520 weed
530 unidentified object
P parametrization
PI improved parametrization
R image analysis result
S treatment controlling signal
S10 taking image
S20 recognizing items by first image recognition analysis
S30 identifying unsatisfying image analysis result
S40 determining ambient data
S50 recognizing items by second image recognition analysis
S60 determining improve parametrization
S70 controlling treatment arrangement
| Number | Date | Country | Kind |
|---|---|---|---|
| 19175363.1 | May 2019 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2020/063967 | 5/19/2020 | WO |
