Radio frequency front end module with high band selectivity

The invention claimed is: 1. A radio frequency front end module for transmitting and receiving radio frequency signals, the front end module comprising: a plurality of external filters, wherein the plurality of external filters include different pass bands; a control lead configured to supply a control signal to dynamically couple an external filter of the plurality of external filters to an integrated circuit during operation of the front end module; the front end module configured to dynamically adjust characteristics of the external filter to process signals from a different frequency band; and the integrated circuit coupled with the external filter via two external filter leads, the integrated circuit including: a transmit-receive switch having a transmit port, a receive port and an antenna port, the transmit-receive switch during operation alternates between coupling the antenna port to the transmit port and coupling the antenna port to the receive port; a power amplifier configured to amplify a modulated radio frequency signal, the transmit-receive switch outputs the amplified modulated radio frequency signal when the antenna port is coupled to the transmit port; a low pass filter coupled between the power amplifier and the transmit port of the transmit-receive switch, the low pass filter configured to pass low-frequency signals and attenuate signals with frequencies higher than a cutoff frequency; a low noise amplifier configured to amplify a received radio frequency signal when the antenna port is coupled to the receive port; and the two external filter leads coupling the external filter between the low noise amplifier of the integrated circuit and the receive port of the transmit-receive switch of the integrated circuit. 2. The front end module of claim 1 , wherein the external filter is a band pass filter configured to pass signals at frequencies within a pass band among the different pass bands and attenuates signals at other frequencies outside the pass band. 3. The front end module of claim 2 , wherein the pass band of the external filter matches a frequency band of radio frequency signals that the front end module is designed to process. 4. The front end module of claim 2 , wherein the external filter is a tunable band pass filter configured to adjust the pass band dynamically during operation of the front end module. 5. The front end module of claim 1 , wherein the power amplifier is a multistage amplifier. 6. The front end module of claim 1 , wherein the power amplifier is configured to output a radio frequency signal having a power of more than 100 mW. 7. The front end module of claim 1 , wherein the power amplifier is configured to output a radio frequency signal having a power of more than 500 mW. 8. The front end module of claim 1 , wherein dimensions of the integrated circuit is less than or equals to 7×5 mm2. 9. The front end module of claim 1 , further comprising: a power lead to supply electrical power to the integrated circuit for operation; and wherein the integrated circuit configured to operate at two different voltages. 10. The front end module of claim 1 , wherein the external filter is a discrete electronic component. 11. The front end module of claim 1 , further comprising: a control signal lead configured to supply the control signal to turn off the power amplifier, or to bypass the low noise amplifier. 12. The front end module of claim 1 , wherein the low pass filter is an integrated passive device that serves as a harmonic filter. 13. A method for transmitting and receiving radio frequency signals, the method comprising: receiving an input radio frequency signal at an antenna; supplying a control signal to dynamically couple a band pass filter of a plurality of external filters to an integrated circuit during operation of the front end module, wherein the plurality of external filters include different pass bands; dynamically adjusting characteristics of the band pass filter external to the integrated circuit to process signals from a different frequency band; when a transmit-receive switch within the integrated circuit is switched to a receive side, transmitting the input radio frequency signal to the band pass filter external to the integrated circuit for attenuating signals outside of a pass band of the band pass filter; amplifying the input radio frequency signal at a low noise amplifier within the integrated circuit; amplifying an output radio frequency signal at a power amplifier within the integrated circuit; attenuating, by a low pass filter within the integrated circuit, signals of the output radio frequency signal that have frequencies higher than a cutoff frequency of the low pass filter; when the transmit-receive switch within the integrated circuit is switched to a transmit side, transmitting the output radio frequency signal to the antenna via the transmit-receive switch; and transmitting the output radio frequency signal at the antenna. 14. The method of claim 13 , further comprising: extracting an information-bearing signal from the input radio frequency signal by demodulating the input radio frequency signal. 15. The method of claim 13 , further comprising: generating the output radio frequency by modulating an information signal with a carrier wave. 16. The method of claim 13 , wherein a radio frequency power of the output radio frequency signal is more than 100 mW when the output radio frequency signal leaves the integrated circuit.