Multiband repeater architecture

What is claimed is: 1. A repeater comprising: a server port; a donor port; a first first-direction amplification and filtering path coupled between the server port and the donor port, wherein the first-direction amplification and filtering path is configured to pass a first-direction signal of a first band and a first-direction signal of a second band through a first bandpass filter; a first second-direction amplification and filtering path coupled between the server port and the donor port, wherein the first second-direction amplification and filtering path is configured to pass a second-direction signal of the first band and a second-direction signal of a third band through a second bandpass filter; a second first-direction amplification and filtering path coupled between the server port and the donor port, wherein the second first-direction amplification and filtering path is configured to pass a first-direction signal of the third band through a third bandpass filter; and a second second-direction amplification and filtering path coupled between the server port and the donor port, wherein the second second-direction amplification and filtering path is configured to pass a second-direction signal of the second band through a fourth bandpass filter; wherein: the first-direction signal of the second band comprises a first first-direction subset band that includes a first first-direction subset bandwidth less than a bandwidth of the first-direction signal of the second band; the second-direction signal of the second band comprises a first second-direction subset band that includes a first second-direction subset bandwidth less than a bandwidth of the second-direction signal of the second band; the first-direction signal of the third band comprises a second first-direction subset band that includes a second first-direction subset bandwidth less than a bandwidth of the first-direction signal of the third band; and the second-direction signal of the third band comprises a second second-direction subset band that includes a second second-direction subset bandwidth less than a bandwidth of the second-direction signal of the third band. 2. The repeater of claim 1 , wherein the first-direction signal is an uplink (UL) direction and the second-direction signal is a downlink (DL) direction. 3. The repeater of claim 2 , further comprising: one or more power detectors configured to: detect a maximum power level or a total power level from: the DL signal of the first band and the third band; the DL signal of the second band; and a controller configured to: provide network protection by selecting an allowed maximum noise power or amplified gain level of the UL signal of the first band and the UL signal of the second band based on the detected maximum or total DL signal power level. 4. The repeater of claim 2 , further comprising: one or more power detectors configured to detect a power level from the DL signal of the first band; and a controller configured to provide network protection by selecting a power level of the UL signal of the first band based on the power level from the DL signal of the first band. 5. The repeater of claim 2 , wherein: a bandwidth border for the UL signal of the first band is separated from a bandwidth border for the UL signal of the second band by less than 10 megahertz (MHz); or a bandwidth border for the DL signal of the first band is separated from a bandwidth border for the DL signal of the third band by less than 10 MHz. 6. The repeater of claim 1 , wherein: the first band is Third Generation Partnership Project (3GPP) long term evolution (LTE) band 70, the second band is one or more of 3GPP LTE band 4 or 3GPP LTE band 66, and the third band is one or more of 3GPP LTE band 2 or 3GPP LTE band 25. 7. The repeater of claim 1 , further comprising: a third first-direction amplification and filtering path coupled between the server port and the donor port, wherein the third first-direction amplification and filtering path is configured to pass a first-direction signal of a fourth band through a fifth bandpass filter; and a third second-direction amplification and filtering path coupled between the server port and the donor port, wherein the third second-direction amplification and filtering path is configured to pass a second-direction signal of the fourth band through a sixth bandpass filter. 8. The repeater of claim 7 , wherein the fourth band is Third Generation Partnership Project (3GPP) long term evolution (LTE) band 30. 9. A multiplexer comprising: a common port comprising: a first first-direction filter configured to pass a first-direction signal of a first band and a first-direction signal of a second band; a first second-direction filter configured to pass a second-direction signal of the first band and a second-direction signal of a third band; a second first-direction filter configured to pass a first-direction signal of a third band; and a second second-direction filter configured to pass a second-direction signal of a second band; a first separate port comprising: a third first-direction filter configured to pass the first-direction signal of the first band and the first-direction signal of the second band; a second separate port comprising: a third second-direction filter configured to pass the second-direction signal of the first band and the second-direction signal of the third band; a third separate port comprising: a fourth first-direction filter configured to pass a first-direction signal of the third band; and a fourth separate port comprising: a fourth second-direction filter configured to pass a second-direction signal of the second band. 10. The multiplexer of claim 9 , wherein: the first-direction signal of the second band comprises a first first-direction subset band that includes a first first-direction subset bandwidth less than a bandwidth of the first-direction signal of the second band; the second-direction signal of the second band comprises a first second-direction subset band that includes a first second-direction subset bandwidth less than a bandwidth of the second-direction signal of the second band; the first-direction signal of the third band comprises a second first-direction subset band that includes a second first-direction subset bandwidth less than a bandwidth of the first-direction signal of the third band; and the second-direction signal of the third band comprises a second second-direction subset band that includes a second second-direction subset bandwidth less than a bandwidth of the second-direction signal of the third band. 11. The multiplexer of claim 9 , wherein: a bandwidth border for the first-direction signal of the first band is separated from a bandwidth border for the first-direction signal of the second band by less than 10 megahertz (MHz); or a bandwidth border for the second-direction signal of the first band is separated from a bandwidth border for the second-direction signal of the third band by less than 10 MHz. 12. The multiplexer of claim 9 , wherein: the first band is Third Generation Partnership Project (3GPP) long term evolution (LTE) band 70, the second band is one or more of 3GPP LTE band 4 or 3GPP LTE band 66, and the third band is one or more of 3GPP LTE band 2 or 3GPP LTE band 25. 13. The multiplexer of claim 9 , further comprising: the common port further comprising: a fifth first-direction filter configured to pass a first-direction signal of a fourth band; and a fifth second-direction filter configured to pass a second-direction signal of the fourth band; a fifth separate port com