A system for determining the gender and/or fertility status of avian eggs including a sampling apparatus and an electromagnetic radiation transmitter and detector. In certain embodiments, the transmitter operates in the terahertz range. The sampling apparatus can be coupled to an avian egg. The sampling apparatus includes a vacuum source, a gas collection device, and a membrane that can be positioned in the passageway coupling the vacuum source to the gas collection device. The membrane is capable of capturing volatile organic compounds. The sampling apparatus applies a vacuum from the vacuum source to the gas proximate to the avian egg and directs the gas captured from the vicinity of the egg toward the membrane. Subsequently, the membrane is positioned within the electromagnetic radiation emitted by the transmitter, generating a spectrum which can be analyzed to determine whether the egg is fertile or infertile, and if fertile, whether the egg is male or female. In an embodiment, the captured volatile organic compounds are

A system for determining the gender and/or fertility status of avian eggs including a sampling apparatus and an electromagnetic radiation transmitter and detector. In certain embodiments, the transmitter operates in the terahertz range. The sampling apparatus can be coupled to an avian egg. The sampling apparatus includes a vacuum source, a gas collection device, and a membrane that can be positioned in the passageway coupling the vacuum source to the gas collection device. The membrane is capable of capturing volatile organic compounds. The sampling apparatus applies a vacuum from the vacuum source to the gas proximate to the avian egg and directs the gas captured from the vicinity of the egg toward the membrane. Subsequently, the membrane is positioned within the electromagnetic radiation emitted by the transmitter, generating a spectrum which can be analyzed to determine whether the egg is fertile or infertile, and if fertile, whether the egg is male or female. In an embodiment, the captured volatile organic compounds are

An apparatus to identify upside-down eggs of a batch of eggs includes a heating module configured to expose an air cell in each egg of the batch of eggs to a radiation flux. The apparatus also includes an imaging module with a thermal camera configured to capture thermal images of the batch of eggs when the eggs are not exposed to the radiation flux. The apparatus further includes an analyzer module configured to detect the presence of a heated zone in the air cell of each egg from the thermal images and identify upside-down eggs based on the presence of the heated zone. A method to identify upside-down eggs from a batch of eggs includes heating the batch of eggs with a radiation source, such as an infrared source, so as to generate a hot zone inside an air cell of each egg without significantly heating the rest of the eggs. Thermal images of the eggs are captured while the eggs are not exposed to the radiation source, analyzed to detect the presence of the hot zone and to identify the upside down eggs.

An apparatus to identify upside-down eggs of a batch of eggs includes a heating module configured to expose an air cell in each egg of the batch of eggs to a radiation flux. The apparatus also includes an imaging module with a thermal camera configured to capture thermal images of the batch of eggs when the eggs are not exposed to the radiation flux. The apparatus further includes an analyzer module configured to detect the presence of a heated zone in the air cell of each egg from the thermal images and identify upside-down eggs based on the presence of the heated zone. A method to identify upside-down eggs from a batch of eggs includes heating the batch of eggs with a radiation source, such as an infrared source, so as to generate a hot zone inside an air cell of each egg without significantly heating the rest of the eggs. Thermal images of the eggs are captured while the eggs are not exposed to the radiation source, analyzed to detect the presence of the hot zone and to identify the upside down eggs.

Shown herein is a method of automated noninvasive determining the fertility of a bird's egg (14), comprising the following steps: conveying a plurality of bird eggs (14) sequentially or in parallel into an NMR apparatus (18), subjecting the bird eggs (14) to an NMR measurement, such as to generate a .sub.3-D NMR image of at least a part of each of said eggs (14), said .sub.3-D NMR image having a spatial resolution in at least one dimension of 1.0 mm or less, preferably of 0.50 mm or less, wherein said part of the egg (14) includes the germinal disc of the respective egg (14), determining a prediction of the fertility according to at least one of the following two procedures: (i) deriving at least one feature from each of said .sub.3-D NMR images, and employing said at least one feature in a feature-based classifier for determining a prediction of the fertility, and (ii) using a deep learning algorithm, and in particular a deep learning algorithm based on convolutional neural networks, generative adversarial networks, recurrent neural networks or long short-term memory networks.

Disclosed herein is a method of automated noninvasive determining the sex of an embryo of a bird's egg (14) as well as a corresponding apparatus. The method comprises the following steps: conveying a plurality of bird eggs (14) sequentially or in parallel into an NMR apparatus (18), subjecting the bird eggs (14) to an NMR measurement, to thereby determine, for each of said eggs (14), one or more NMR parameters associated with the egg (14) selected from the group consisting of a Ti relaxation time, a T2 relaxation time and a diffusion coefficient, forwarding said one or more NMR parameters, or parameters derived therefrom, to a classification module (38), said classification module (38) configured for determining, based on said one or more NMR parameters or parameters derived therefrom, a prediction of the sex of the embryo of the associated egg (14), and conveying said plurality of bird eggs (14) out of said NMR apparatus (18) and sorting the eggs (14) according to the sex prediction provided by said classification module (38).

Disclosed herein is a method of automated noninvasive determining the sex of an embryo of a bird's egg (14) as well as a corresponding apparatus. The method comprises the following steps: conveying a plurality of bird eggs (14) sequentially or in parallel into an NMR apparatus (18), subjecting the bird eggs (14) to an NMR measurement, to thereby determine, for each of said eggs (14), one or more NMR parameters associated with the egg (14) selected from the group consisting of a Ti relaxation time, a T2 relaxation time and a diffusion coefficient, forwarding said one or more NMR parameters, or parameters derived therefrom, to a classification module (38), said classification module (38) configured for determining, based on said one or more NMR parameters or parameters derived therefrom, a prediction of the sex of the embryo of the associated egg (14), and conveying said plurality of bird eggs (14) out of said NMR apparatus (18) and sorting the eggs (14) according to the sex prediction provided by said classification module (38).

A system, egg holding unit and methods are for non-invasively determining the fertility of an avian egg. The system includes an egg holding unit; at least one transmitter, operative for transmitting electromagnetic waves towards the at least one egg; and at least one receiver for receiving a received signal, including at least a portion of the electromagnetic waves after passing through the at least one egg placed within the egg holding unit. A processor is adapted to analyze the received signal according to a predetermined fertility determination procedure. A communication interface provides a fertility indication with respect to each one of the at least one egg. The communication interface may be coupled to a display device adapted to show fertilization data using a GUI, to one or more end users.

A system, egg holding unit and methods are for non-invasively determining the fertility of an avian egg. The system includes an egg holding unit; at least one transmitter, operative for transmitting electromagnetic waves towards the at least one egg; and at least one receiver for receiving a received signal, including at least a portion of the electromagnetic waves after passing through the at least one egg placed within the egg holding unit. A processor is adapted to analyze the received signal according to a predetermined fertility determination procedure. A communication interface provides a fertility indication with respect to each one of the at least one egg. The communication interface may be coupled to a display device adapted to show fertilization data using a GUI, to one or more end users.

An egg grasp device is provided. Such a device includes a body and a plurality of elongated members extending from the body. The elongated members are interlaced to form a sheath capable of retaining an egg. The sheath has a distal end and a proximal end at which the elongated members are operably engaged with the body. The elongated members cooperate to define an opening at the distal end through which an egg is received when the elongated members engage and deflect about an egg such that the egg is seated within the sheath. Associated systems and methods are also provided.