Abstract: A resistance-band exercise monitoring device includes a first force sensor that senses a first force applied to a first resistance band, a second force sensor that senses a second force applied to a second resistance band, a single electronics module with a single transceiver for wirelessly communicating with a remote device, and a flexible strap physically coupling with the first and second resistance bands. The flexible strap has conductive pathways electrically coupling the force sensors to the single electronics module. The single electronics module communicates values indicative of the first and second forces to the remote device via the single transceiver. The flexible strap does not stretch and protects the conductive pathways from excessive stress. The resistance-band exercise monitoring device may be configured in multiple ways to perform a wide variety of exercises.

Abstract: A resistance-band exercise monitoring device includes a first force sensor that senses a first force applied to a first resistance band, a second force sensor that senses a second force applied to a second resistance band, a single electronics module with a single transceiver for wirelessly communicating with a remote device, and a flexible strap physically coupling with the first and second resistance bands. The flexible strap has conductive pathways electrically coupling the force sensors to the single electronics module. The single electronics module communicates values indicative of the first and second forces to the remote device via the single transceiver. The flexible strap does not stretch and protects the conductive pathways from excessive stress. The resistance-band exercise monitoring device may be configured in multiple ways to perform a wide variety of exercises.

Abstract: A resistance-band exercise monitoring device includes a first force sensor that senses a first force applied to a first resistance band, a second force sensor that senses a second force applied to a second resistance band, a single electronics module with a single transceiver for wirelessly communicating with a remote device, and a flexible strap physically coupling with the first and second resistance bands. The flexible strap has conductive pathways electrically coupling the force sensors to the single electronics module. The single electronics module communicates values indicative of the first and second forces to the remote device via the single transceiver. The flexible strap does not stretch and protects the conductive pathways from excessive stress. The resistance-band exercise monitoring device may be configured in multiple ways to perform a wide variety of exercises.

Abstract: A resistance-band exercise monitoring device includes a first force sensor that senses a first force applied to a first resistance band, a second force sensor that senses a second force applied to a second resistance band, a single electronics module with a single transceiver for wirelessly communicating with a remote device, and a flexible strap physically coupling with the first and second resistance bands. The flexible strap has conductive pathways electrically coupling the force sensors to the single electronics module. The single electronics module communicates values indicative of the first and second forces to the remote device via the single transceiver. The flexible strap does not stretch and protects the conductive pathways from excessive stress. The resistance-band exercise monitoring device may be configured in multiple ways to perform a wide variety of exercises.

Abstract: A partially non-rigid solar capture mounting system which reduces the risk of damage due to wind is disclosed. The solar capture mounting system includes at least one pole, a horizontal beam mounted to the pole, and at least one backing plate hanging from the horizontal beam via a pivotal connection. Examples of pivotal connection are bushings with ball bearings, hinges, steel rings and spring clips. Each of the backing plates supports at least one solar cell. Wind pressure against a backing plate pivots the backing plate about the horizontal beam such that the system experiences reduced stress and reduced risk of damage due to wind and wind carried objects.

Abstract: A partially non-rigid solar capture mounting system which reduces the risk of damage due to wind is disclosed. The solar capture mounting system includes at least one pole, a horizontal beam mounted to the pole, and at least one backing plate hanging from the horizontal beam via a pivotal connection. Examples of pivotal connection are bushings with ball bearings, hinges, steel rings and spring clips. Each of the backing plates supports at least one solar cell. Wind pressure against a backing plate pivots the backing plate about the horizontal beam such that the system experiences reduced stress and reduced risk of damage due to wind and wind carried objects.