Abstract: Described herein are systems and methods for generating a cyber-deception strategy that adaptively implement a decoy file placement strategy for thwarting malicious activity on a computing network. The systems and methods can include a plurality of surveillance services that can monitor the evolving conditions and states of a target computing network. The information from the external surveillance services can be combined with one or more user defined parameters to serve as inputs to a system that can use the input data to generate a decoy file content and placement strategy so as to effect a cyber-deception strategy. In one or more examples, can identify one or more target objects to use as decoys and use the identified targeted objects as well as information about the target network, to generate a high-level guidelines that will be used to generate one or more deception plans for implementation on the target network.

Abstract: A computer-implemented method of learning sensory media association includes receiving a first type of nontext input and a second type of nontext input; encoding and decoding the first type of nontext input using a first autoencoder having a first convolutional neural network, and the second type of nontext input using a second autoencoder having a second convolutional neural network; bridging first autoencoder representations and second autoencoder representations by a deep neural network that learns mappings between the first autoencoder representations associated with a first modality and the second autoencoder representations associated with a second modality; and based on the encoding, decoding, and the bridging, generating a first type of nontext output and a second type of nontext output based on the first type of nontext input or the second type of nontext input in either the first modality or the second modality.

Abstract: Methods for generating synthetic genomes, for example synthetic genomes having desired properties or viable genomes of reduced size, are disclosed. Also disclosed are synthetic genomes produced by the methods disclosed herein and synthetic cells containing the synthetic genomes disclosed herein.

Abstract: Methods for generating synthetic genomes, for example synthetic genomes having desired properties or viable genomes of reduced size, are disclosed. Also disclosed are synthetic genomes produced by the methods disclosed herein and synthetic cells containing the synthetic genomes disclosed herein.

Abstract: Compositions and methods are disclosed herein for cloning a synthetic or a semi-synthetic donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: A computer-implemented method of learning sensory media association includes receiving a first type of nontext input and a second type of nontext input; encoding and decoding the first type of nontext input using a first autoencoder having a first convolutional neural network, and the second type of nontext input using a second autoencoder having a second convolutional neural network; bridging first autoencoder representations and second autoencoder representations by a deep neural network that learns mappings between the first autoencoder representations associated with a first modality and the second autoencoder representations associated with a second modality; and based on the encoding, decoding, and the bridging, generating a first type of nontext output and a second type of nontext output based on the first type of nontext input or the second type of nontext input in either the first modality or the second modality.

Abstract: Methods for generating synthetic genomes, for example synthetic genomes having desired properties or viable genomes of reduced size, are disclosed. Also disclosed are synthetic genomes produced by the methods disclosed herein and synthetic cells containing the synthetic genomes disclosed herein.

Abstract: Compositions and methods are disclosed herein for cloning a donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: Compositions and methods are disclosed herein for cloning a synthetic or a semi-synthetic donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: Compositions and methods are disclosed herein for cloning a donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: Compositions and methods are disclosed herein for cloning a synthetic or a semi-synthetic donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: Compositions and methods are disclosed herein for cloning a donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: Compositions and methods are disclosed herein for cloning a synthetic or a semi-synthetic donor genome in a heterologous host cell. In one embodiment, the donor genome can be further modified within a host cell. Modified or unmodified genomes can be further isolated from the host cell and transferred to a recipient cell. Methods disclosed herein can be used to alter donor genomes from intractable donor cells in more tractable host cells.

Abstract: The interface control system of this invention renders a high speed CPU compatible with low speed expansion devices such as expansion interfaces. The system causes the CPU clock signal to be in phase with the interface clock signal at the end of the last cycle of an interface cycle. At the end of the interface cycle, the system selects between a positive high speed and a negative high speed clock to be the CPU clock signal applied to the CPU.

Abstract: A debug interface for use in debugging a microprocessor during development. The debug interface is connected with a host computer for the bidirectional data transmissions and utilizes a ROM socket on the object system to communicate with the object system being debugged. The object system can read data from the debug interface only, but cannot write data thereto. The testing software program in the host computer is entered into an SRAM on the debug interface through a host computer data bus. When the content of the registers in the object system is required by the software, the data needed are dumped onto the object system address bus by software techniques; then through an input port, connecting the object system address bus to the host computer data bus, the data can be received by the host computer, and so displayed on the monitor of the host computer.