Measuring unit and a method for measuring transmission parameters of a device under test

The invention claimed is: 1. A measuring unit for measuring transmission parameters of a device under test, comprising: a control unit; a transmitter and receiver unit; and an evaluation unit, wherein the transmitter and receiver unit is connected via a first connection to the control unit and via at least one transmission channel to the device under test, wherein acknowledgement-data packets are transmitted as control-data packets, wherein the device under test is connected via a second connection to the evaluation unit, wherein, for the measurement of the transmission parameters of the device under test, the control-data packets and test-data packets are transmitted separately between the control unit and the evaluation unit, wherein the at least one transmission channel for the test-data packets can be disturbed in a targeted manner, wherein, dependent upon whether an uplink path or a downlink path of the device under test is to be tested, a respective other path in the at least one transmission channel is not disturbed, so that the acknowledgement-data packets can be transmitted in an undisturbed manner, wherein the test-data packets are delayed before transmission, wherein the control unit and the evaluation unit access a same clock, wherein no time is wasted while the disturbed transmission channel is being switched to an undisturbed transmission channel, wherein full-duplex measurements of connection-orientated protocols are allowed, and wherein a segment of one of the test-data packets contains the test data to be transmitted, which is generated by a pseudorandom noise generator, wherein the pseudorandom noise generator is a linear-feedback shift register. 2. The measuring unit according to claim 1 , wherein the at least one transmission channel is a simulated radio-transmission channel. 3. The measuring unit according to claim 1 , wherein the at least one transmission channel is not disturbed during the transmission of the control-data packets. 4. The measuring unit according to claim 1 , wherein interference, such as multiple fading and/or noise, can be added to the transmission channel. 5. The measuring unit according to claim 1 , wherein the control-data packets can be transmitted via the undisturbed transmission channel or via at least one further undisturbed connection. 6. The measuring unit according to claim 5 , wherein the at least one further undisturbed connection is a direct connection between the control unit and the evaluation unit. 7. The measuring unit according to claim 1 , wherein the measurement of the transmission parameters is selected from the group consisting of a throughput measurement, a latency time measurement, a round-trip-delay measurement, a jitter measurement, a packet-error rate, and combinations thereof. 8. The measuring unit according to claim 1 , wherein the control unit and the evaluation unit are embodied in a common computer system. 9. A method for measuring transmission parameters of a device under test with a measuring unit, which comprises a control unit, a transmitter and receiver unit, and an evaluation unit, wherein the transmitter and receiver unit is connected via a first connection to the control unit and via a transmission channel to the device under test, wherein acknowledgement-data packets are transmitted as control-data packets, wherein the device under test is connected via a second connection to the evaluation unit, and wherein, dependent upon whether an uplink path or a downlink path of the device under test is to be tested, a respective other path in the transmission channel is not disturbed, so that the acknowledgement-data packets can be transmitted in an undisturbed manner, the method comprising: transmitting control-data packets between the control unit and the evaluation unit; targeting interference of the transmission channel which is used for transmitting test-data packets between the control unit and the evaluation unit; and transmitting test-data packets between the control unit and the evaluation unit, wherein the test-data packets are delayed before transmission, wherein the control unit and the evaluation unit access a same clock, wherein no time is wasted while the disturbed transmission channel is being switched to an undisturbed transmission channel, wherein full-duplex measurements of connection-orientated protocols are allowed, and wherein a segment of one of the test-data packets contains the test data to be transmitted, which is generated by a pseudorandom noise generator, wherein the pseudorandom noise generator is a linear-feedback shift register. 10. The method according to claim 9 , further comprising: starting a clock in the control unit or the evaluation unit, as soon as test-data packets are transmitted or received; stopping the clock in the control unit or the evaluation unit, as soon as further test-data packets or acknowledgement-data packets are received; and adding the time elapsed to a buffer unit, and incrementing the number of received test-data packets or acknowledgement-data packets. 11. The method according to claim 9 , further comprising: switching the interference off as soon as control-data packets are transmitted, or transmitting the control-data packets on a further, undisturbed connection between the control unit and the evaluation unit. 12. The method according to claim 9 , further comprising: transmitting an instruction, as a control-data packet, that all test-data packets have been transmitted from the control unit to the evaluation unit or from the evaluation unit to the control unit. 13. The method according to claim 12 , further comprising: calculating the transmission parameters with the control unit or the evaluation unit. 14. The method according to claim 13 , further comprising: preparing a test protocol by the control unit. 15. The measuring unit according to claim 1 , wherein the control unit and the evaluation unit are embodied jointly in a computer system of the transmitter and receiver unit. 16. The measuring unit according to claim 2 , wherein the transmission channel is a simulated radio-transmission channel according to the Long Term Evolution (LTE) standard, the Worldwide Interoperability for Microwave Access (WiMAX) standard, the Wireless Local Area Network (WLAN) standard, or the Universal Mobile Telecommunications System (UMTS) standard. 17. The method according to claim 13 , wherein the transmission parameters are selected from the group consisting of data throughput, latency, round-trip delay, jitter, packet-error rate, and combinations thereof. 18. The method according to claim 13 , further comprising: preparing a test protocol; and communicating the test protocol to the control unit as a control-data packet by the evaluation unit.