Cognitive HF radio with tuned compact antenna

What is claimed is: 1. An HF transceiver having: a transmit-receive module capable of transmitting and receiving radio signals within the HF band; a first switching network electrically connected to the transmit-receive module; at least one impedance-matching circuit connected to the first switching network; a second switching network connected to the at least one impedance-matching circuit; and an electrically small antenna electrically connected to the second switching network, wherein the at least one impedance-matching circuit includes non-Foster elements having negative impedance over a preselected frequency range, wherein the at least one impedance-matching circuit comprises multiple impedance matching circuits, each of the multiple impedance matching circuits having an impedance designed to impedance match the electrically small antenna to the transmit-receive module at a predetermined transmit frequency, and wherein the first and second switching networks alternatively connect the transmit-receive module and the electrically small antenna to one of the multiple impedance matching circuits. 2. A method of sending an HF radio signal with a configurable HF transceiver in communication with a cognitive engine (CE), the method comprising: detecting a first set of environmental transmit conditions indicating radio propagation conditions of the ionosphere at a first time in the HF band; detecting a first set of transmit configuration conditions of the HF transceiver at the first time; transmitting an HF signal under the first set of environmental and transmit configuration conditions at the first time; receiving feedback from a receiver indicating a degree to which the transmitted HF signal has been or has not been successfully received; and storing data relating to the first set of transmit configuration conditions, the first set of environmental transmit conditions and the received feedback in a database. 3. The method of claim 2 , further comprising: if the stored data indicates that a transmitted signal has historically been successfully received under the first set of environmental transmit conditions and the first set of transmit configuration conditions, configuring the HF transceiver in accordance with the first set of transmit configuration conditions upon sensing a recurrence of the first set of environmental transmit conditions. 4. The method of claim 2 , further comprising if the stored data indicates that a transmitted signal has historically been successfully received under the first set of environmental transmit conditions and the first set of transmit configuration conditions, configuring the HF transceiver to transmit an HF signal under a second set of transmission configuration conditions and in accordance with the first set of transmit configuration conditions upon sensing a recurrence of the first set of environmental transmit conditions. 5. The method of claim 2 , further comprising: if the stored data indicates that a transmitted signal has not been successfully received under the first set of environmental transmit conditions and the first set of transmit configuration conditions, configuring the HF transceiver in accordance with a second set of transmit configuration conditions, and receiving feedback from a receiver indicating that the transmitted HF signal has been or has not been successfully received. 6. The method of claim 2 , wherein the feedback from a receiver indicating that the transmitted signal has been or has not been successfully received comprises a number of successfully received and failed packets, respectively. 7. The method of claim 2 , wherein the first set of environmental transmit conditions further comprises information regarding the locations of the transceiver and a receiver. 8. The method of claim 2 , further comprising configuring the HF transceiver in accordance with a second set of transmit configuration conditions on the basis of stored data relating to previous sets of transmit configuration conditions and environmental transmit conditions. 9. The method of claim 2 , wherein configuring the HF transceiver comprises altering one or more of the following: modulation, coding, pulse shape, and transmit power. 10. The method of claim 2 , wherein the first set of environmental transmit conditions indicating radio propagation conditions of the ionosphere at the first time in the HF band comprises one or more of: real-time maximum-usable frequency (“MUF”) maps, solar flux index, and geomagnetic storm conditions. 11. The method of claim 2 , further comprising: storing records relating to the success or failure of previous HF transmissions, the record including data regarding previous environmental conditions indicating radio propagation conditions of the ionosphere at a first time in the HF band at times of the previous transmissions and previous transmission conditions under which the previous transmissions were sent; and on the basis of stored records relating to the historical success or failure of the previous transmissions under previous environmental and transmission conditions, and on the basis of contemporarily sensed environmental conditions: predicting a set of transmission conditions including a transmission frequency in the HF band likely to result in favorable radio propagation conditions in the HF band within the ionosphere; and causing the HF transceiver to transmit under the predicted set of transmission conditions. 12. An HF radio system, comprising: an HF transceiver configurable to transmit an HF signal under a variety of transmit parameters; an antenna in electronic communication with the HF transceiver; a sensing module connected to one or more data inputs; a programmable processor, and non-volatile storage including computer readable instructions executable by the programmable processor to cause the programmable processor to: determine a first set of environmental parameters indicating radio propagation conditions of the ionosphere in the HF band sensed by the sensing module at a first time, determine a first set of transmission parameters of the HF transceiver determined by a configuration of the HF transceiver at the first time; determine whether a first transmission sent by the HF transceiver under the first set of environmental and transmission parameters was successfully received by a receiver. 13. The system of claim 12 , wherein the non-volatile storage includes computer readable instructions executable by a programmable processor to cause the programmable processor to: store a record relating to the success or failure of the first transmission in the non-volatile storage, that record including data regarding the environmental and transmission conditions under which the transmission was sent. 14. The system of claim 13 , wherein the non-volatile storage includes computer readable instructions executable by a programmable processor to cause the programmable processor to: on the basis of stored records relating to the historical success or failure of previous transmissions under previous environmental and transmission conditions, and on the basis of contemporarily sensed environmental conditions: predict a set of transmission conditions including a transmission frequency in the HF band likely to result in favorable radio propagation conditions in the HF band within the ionosphere; and cause the HF transceiver to transmit under the predicted set of transmission conditions.