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A holster (10) for a telecommunication device (12), such as a cellular telephone or wireless telephone, includes a housing (14) adapted to removably support the telecommunication device (12). The holster (10) also includes an earpiece assembly (52) including at least one transducer, such as an earbu

A holster (10) for a telecommunication device (12), such as a cellular telephone or wireless telephone, includes a housing (14) adapted to removably support the telecommunication device (12). The holster (10) also includes an earpiece assembly (52) including at least one transducer, such as an earbud (53) or a microphone (54), and a cord (56) depending from the at least one transducer (53, 54). The earpiece assembly (52) is extendable and retractable relative to the housing (14). The holster (10) further includes an extension/retraction assembly (32) having a spool (34) for taking up at least a portion of the cord (56) when the earpiece assembly (52) is retracted relative to the housing (14), and at least one coil spring (35) adapted to rotate the spool (34). The at least one coil spring (35) can electrically couple the at least one transducer (53, 54) to the telecommunication device (12).

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A holster (10) for a telecommunication device (12), such as a cellular telephone or wireless telephone, includes a housing (14) adapted to removably support the telecommunication device (12). The holster (10) also includes an earpiece assembly (52) including at least one transducer, such as an earbu

A holster (10) for a telecommunication device (12), such as a cellular telephone or wireless telephone, includes a housing (14) adapted to removably support the telecommunication device (12). The holster (10) also includes an earpiece assembly (52) including at least one transducer, such as an earbud (53) or a microphone (54), and a cord (56) depending from the at least one transducer (53, 54). The earpiece assembly (52) is extendable and retractable relative to the housing (14). The holster (10) further includes an extension/retraction assembly (32) having a spool (34) for taking up at least a portion of the cord (56) when the earpiece assembly (52) is retracted relative to the housing (14), and at least one coil spring (35) adapted to rotate the spool (34). The at least one coil spring (35) can electrically couple the at least one transducer (53, 54) to the telecommunication device (12). tion in the digital domain following a combining of the plurality of modulated channels and before a location in the digital domain where power of the combined digital baseband signal for the first carrier frequency is determined. 7. The method of claim 1, further comprising the step of applying a breathing factor to the digital baseband signal for the first carrier frequency at a location in the digital domain following a combining of the plurality of modulated channels. 8. The method of claim 1, wherein the gain adjustment factor or value is applied to the digital baseband signal prior to a summer which sums the signal for the first carrier frequency with one or more other carrier frequencies. 9. A method of controlling output power of a transmitter, the method comprising the steps of: combining a plurality of modulated channels into a combined digital baseband signal for a first carrier frequency; determining, in a digital domain, a power of the combined digital baseband signal; converting the digital baseband signal to an analog signal; determining power of the analog signal for the first carrier frequency; calculating a gain value utilizing at least the determined power of the combined digital baseband signal and the determined power of the analog signal; determining a gain adjustment factor or value utilizing at least the calculated gain value and a target gain; and applying the gain adjustment factor or value to a digital baseband signal for the first carrier frequency in the transmitter in order to adjust the gain of the transmitter toward the target gain. 10. The method of claim 9, wherein said step of determining power of the analog signal for the first carrier frequency further comprises excluding at least a second carrier frequency to be transmitted by the transmitter; and the method further comprising the step of the transmitter transmitting each of the first and second carrier frequencies in a wireless manner. 11. The method of claim 10, further comprising the steps of: determining, in the digital domain, a power of a combined digital baseband signal for the second carrier frequency; determining power of the analog signal for the second carrier frequency while excluding the first carrier frequency; determining a gain adjustment factor or value for the second carrier frequency, wherein the gain adjustment factor or value for the second carrier frequency is different than the gain adjustment factor or value for the first carrier frequency; and applying the gain adjustment factor or value for the second carrier frequency to a digital baseband signal for the second carrier frequency in the digital domain in order to adjust the gain of the transmitter toward the target gain. 12. The method of claim 9, wherein the transmitter is a base station in a cellular telecommunications network. 13. The method of claim 12, wherein the base station is a CDMA base station. 14. The method of claim 9, wherein said step of calculating a gain value comprises combining the determined power of the analog signal with a calibration factor relating to the transmitter so as to obtain a first power value. 15. The method of claim 14, further comprising determining a difference between the first power value and the power of the combined digital baseband signal to obtain the gain value. 16. The method of claim 15, further comprising determining a difference between the gain value and the target gain to obtain the gain adjustment factor or value. 17. The method of claim 15, further comprising applying the gain adjustment factor or value to the digital baseband signal for the first carrier frequency at a location in the digital domain following a combining of the plurality of modulated channels and before a location in the digital domain where power of the combined digital baseband signal for the first carrier frequency is determined. 18. The method of claim 9, wherein the gain adjustment factor or value is applied to the digita l baseband signal prior to a summer which sums the signal for the first carrier frequency with one or more other carrier frequencies. 19. A base station in a wideband code division multiple access (WCDMA) cellular telecommunications network, the base station comprising: a combiner for combining a plurality of modulated channels into a combined digital baseband signal for a first of a plurality of carrier frequencies to be transmitted by the base station to at least one mobile station located in a cell of the base station; a first baseband power sensor for determining, in a digital domain, a power of the combined digital baseband signal for the first carrier frequency; a digital to analog converter for converting the digital baseband signal to an analog signal; an RF power sensor for determining power of the analog signal for the first carrier frequency; gain calculating circuitry for calculating a gain adjustment factor or value based at least upon a target gain, the determined power of the analog signal, and the determined power of the digital baseband signal; and gain adjustment circuitry for applying the gain adjustment factor or value to a digital baseband signal for the first carrier frequency in order to adjust the gain of the base station toward the target gain. 20. The base station of claim 19, wherein said RF power sensor is frequency selective and when determining power of the analog signal for the first carrier frequency does not determine power of a second carrier frequency also transmitted by the base station; and wherein the base station further comprises a second baseband power sensor for determining, in the digital domain, a power of a combined digital baseband signal for the second carrier frequency. 21. The base station of claim 19, wherein said gain calculating circuitry comprises a summer for combining the determined power of the analog signal with a calibration factor relating to the base station so as to obtain a first power value. 22. The base station of claim 21, wherein said gain calculating circuitry further comprises a first comparator for determining a difference between the first power value and the power of the combined digital baseband signal to obtain the gain value. 23. The base station of claim 22, wherein said gain calculating circuitry further comprises a second comparator for determining a difference between the gain value and the target gain to obtain the gain adjustment factor or value. 24. The base station of claim 23, wherein said gain adjustment circuitry comprises a multiplying function. 25. The base station of claim 19, wherein the gain adjustment factor or value is applied to the digital baseband signal prior to a summer which sums the signal for the first carrier frequency with one or more other carrier frequencies.