Abstract: Wireless communication and proximity-based feedback technologies are disclosed. In some examples, a system identifies, based on analysis of signal(s) (e.g., conveying transaction object information) received by a reader interface from a transaction object in response to physical proximity between the transaction object and the reader interface, an indication of a movement of the transaction object relative to the reader interface. The system generates, based on the indication, feedback indicating a recommended change to the movement to improve an ability of the reader interface to read the transaction object. The system sends the feedback to an output device that to output the feedback to indicate the recommended change. The system reads the transaction object information from the transaction object using the reader interface in response to an improvement in the ability of the reader interface to read the transaction object and in response to the output of the feedback.

Abstract: Wireless communication and proximity-based feedback technologies are disclosed. In some examples, a system identifies that a wireless communication interface has received wireless signal(s) for conveying information from a transaction object in response to proximity between the transaction object and the interface. The system identifies, based on relative signal strength of the signal(s) as received at each of a plurality of antennae of the interface, an indication of a relative position of the transaction object relative to the interface. The system generates, based on the indication of the relative position, feedback indicating a recommended movement of the transaction object relative to the interface to increase signal strength, and sends the feedback to an output device to output the feedback to indicate the recommended movement. The system reads the information from the transaction object using the interface in response to an increase in signal strength and to the outputting of the feedback.

Abstract: Techniques described herein are directed to, among other things, wireless payment readers configured to transition between multiple different power states. In some instances, these power states include one or more relatively low-power states such that an overall battery life of the wireless payment readers are lengthened. Further, in some instances, a point-of-sale (POS) application operating on a POS device that wirelessly couples to an example wireless payment reader may cause the wireless payment reader to transition from one state to another, such as from a first, lower-power state to a second, higher-power state in response to the POS application determining that a payment is to be processed using the wireless payment reader.

Abstract: A point of sale (POS) device includes an output device such as a speaker, a display screen, or a network interface. The POS device also includes a secure enclosure housing a secure processor and tamper detection circuitry for detecting attempts to tamper with the secure enclosure. Use of the output device is shared between the secure processor and a main processor via a switch that is controlled by the secure processor. The secure processor can switch control of the output device from the main processor to itself and can output an output dataset via the output device in a number of scenarios. These scenarios include the secure processor detecting an attempt to tamper with the secure enclosure, the secure processor recognizing that the main processor is behaving suspiciously, or the secure processor wanting to output sensitive information. The output dataset may include visual data, audio data, or network data.

Abstract: A point of sale (POS) device includes an output device such as a speaker, a display screen, or a network interface. The POS device also includes a secure enclosure housing a secure processor and tamper detection circuitry for detecting attempts to tamper with the secure enclosure. Use of the output device is shared between the secure processor and a main processor via a switch that is controlled by the secure processor. The secure processor can switch control of the output device from the main processor to itself and can output an output dataset via the output device in a number of scenarios. These scenarios include the secure processor detecting an attempt to tamper with the secure enclosure, the secure processor recognizing that the main processor is behaving suspiciously, or the secure processor wanting to output sensitive information. The output dataset may include visual data, audio data, or network data.

Abstract: A transaction object reader receives a signal from a user's transaction object when the user's transaction object is in proximity with the transaction object reader. This signal is conveyed from the transaction object reader to a secure processor that reads transaction information from the signal, generates a processed dataset by encrypting or otherwise processing the transaction information, and outputs the processed dataset to a main processor, which uses the processed dataset to conduct a transaction. The signal from the transaction object reader is also conveyed along a second path that bypasses the secure processor, instead going to a filter that filters the signal to attenuate the transaction information and then going to the main processor, which uses the filtered signal to provide feedback to the user identifying how close the transaction object is to the transaction object reader.

Abstract: A transaction object reader receives a signal from a user's transaction object when the user's transaction object is in proximity with the transaction object reader. This signal is conveyed from the transaction object reader to a secure processor that reads transaction information from the signal, generates a processed dataset by encrypting or otherwise processing the transaction information, and outputs the processed dataset to a main processor, which uses the processed dataset to conduct a transaction. The signal from the transaction object reader is also conveyed along a second path that bypasses the secure processor, instead going to a filter that filters the signal to attenuate the transaction information and then going to the main processor, which uses the filtered signal to provide feedback to the user identifying how close the transaction object is to the transaction object reader.