초록 ▼

Transmission power in a frequency-hopping radio system that transmits packets from a sending radio unit to a receiving radio unit, wherein each packet includes an address designating the receiving radio unit, is controlled by measuring received signal strength of packets whose addresses were success

Transmission power in a frequency-hopping radio system that transmits packets from a sending radio unit to a receiving radio unit, wherein each packet includes an address designating the receiving radio unit, is controlled by measuring received signal strength of packets whose addresses were successfully received in the receiving radio unit, regardless of whether other portions of the respective packets were successfully received. An average signal strength value is generated from the received signal strength measurements. The mathematical difference between the average signal strength value and a target value associated with the receiving radio unit is then determined and used as a basis for deciding whether to send a power control message from the receiving radio unit to the sending radio unit. In order to provide a hysteresis in the power control process, a power control message is sent from the receiving radio unit to the sending radio unit if the mathematical difference is greater than a first decision boundary, or if the mathematical difference is less than a second decision boundary. The power control message may itself include the mathematical difference which, when received by the sending radio unit, is used as a basis for determining a transmission power level adjustment amount. The target value, against which the average signal strength value is compared, may be based on the receiver sensitivity adjusted to account for implementation losses and other inaccuracies.

대표청구항 ▼

Transmission power in a frequency-hopping radio system that transmits packets from a sending radio unit to a receiving radio unit, wherein each packet includes an address designating the receiving radio unit, is controlled by measuring received signal strength of packets whose addresses were success

Transmission power in a frequency-hopping radio system that transmits packets from a sending radio unit to a receiving radio unit, wherein each packet includes an address designating the receiving radio unit, is controlled by measuring received signal strength of packets whose addresses were successfully received in the receiving radio unit, regardless of whether other portions of the respective packets were successfully received. An average signal strength value is generated from the received signal strength measurements. The mathematical difference between the average signal strength value and a target value associated with the receiving radio unit is then determined and used as a basis for deciding whether to send a power control message from the receiving radio unit to the sending radio unit. In order to provide a hysteresis in the power control process, a power control message is sent from the receiving radio unit to the sending radio unit if the mathematical difference is greater than a first decision boundary, or if the mathematical difference is less than a second decision boundary. The power control message may itself include the mathematical difference which, when received by the sending radio unit, is used as a basis for determining a transmission power level adjustment amount. The target value, against which the average signal strength value is compared, may be based on the receiver sensitivity adjusted to account for implementation losses and other inaccuracies. second adjustment means for adjusting the amplitude of the second read signal in accordance with an output of said second comparison means. 3. A prepit detecting apparatus according to claim 1, wherein said amplitude correction means incorporates first amplitude extracting means for extracting an average amplitude level of the first read signal, second amplitude extracting means for extracting an average amplitude level of the second read signal, first comparison means for comparing an output of said first amplitude extracting means with a reference level, second comparison means for comparing an output of said second amplitude extracting means with a reference level, first amplitude adjustment means for adjusting the amplitude of the first read signal in accordance with an output of said first comparison means and second adjustment means for adjusting the amplitude of the second read signal in accordance with an output of said second comparison means. 4. A prepit detecting apparatus arranged to use an optical recording medium which has information recording tracks on which information is recorded, which is wobbled in response to a wobble signal having a predetermined frequency and which has guide tracks for guiding a light beam to said information recording track having prepits for saving pre-information and incorporating light receiving means divided into a first divided light receiving portion and a second divided light receiving portion divided along an optically parallel division line in a direction of tangent of the information tracks and arranged to receive reflected light of the light beam with which the optical recording medium has been irradiated and a difference calculator for calculating the difference between a first read signal output from said first divided light receiving portion and a second read signal output from said second divided light receiving portion so that the prepit is detected in response to a differential signal output from said difference calculator, said prepit detecting apparatus comprising: DC clamping means for clamping the differential signal output from said difference calculator with a DC level; and prepit detecting means which compares an output from said clamping means and a reference slice level with each other to detect the prepit signal; wherein said DC clamping means clamps the wobble signal component corresponding to detection timing of the prepit signal detected by said prepit detecting means to the-predetermined DC level. 5. A prepit detecting apparatus according to claim 4, wherein said DC clamping means incorporates relay means for relaying the differential signal at detection timing of the prepit signal, an integrating circuit for integrating the differential signal supplied through said relay means and superimposing means for superimposing an output of said integrating circuit on the differential signal, and said integrating circuit incorporates a calculation amplifier having a non-inverted input terminal to which a predetermined DC level is input and an integrating capacitor connected between an output terminal of said calculation amplifier and an inverted input terminal. 6. A prepit detecting apparatus which uses an optical recording medium having information recording tracks on which information is recorded and guide tracks each of which guides a light beam to the information recording track and on which prepits for saving pre-information are formed such that the light beam is applied to said information track of said optical recording medium, said prepit detecting apparatus comprising: a light receptor divided into a first divided light receiving portion and a second divided light receiving portion divided along an optically parallel division line in a direction of tangent of the information tracks and arranged to receive reflected light of the light beam with which the optical recording medium has been irradiated; and a difference calculator for calculating t he difference between a first read signal output from said first divided light receiving portion and a second read signal output from said second divided light receiving portion so that the prepit is detected in response to a differential signal output from said difference calculator; wherein said difference calculator incorporates an amplitude correction unit for causing the amplitudes of the first read signal and the second read signal to coincide with a reference level, and the difference between the first read signal and the second read signal corrected by said amplitude correction unit is calculated. 7. A prepit detecting apparatus according to claim 1, wherein said amplitude correction unit incorporates a first amplitude extracting unit for extracting an average amplitude level of the first read signal, a second amplitude extracting unit for extracting an average amplitude level of the second read signal, a first comparison unit for comparing an output of said first amplitude extracting unit and an output of said second amplitude extracting unit with each other, a second comparison unit for comparing an output of said second amplitude extracting unit and the reference level with each other, a first amplitude adjustment unit for adjusting the amplitude of the first read signal in accordance with an output of said first comparison unit, and a second adjustment unit for adjusting the amplitude of the second read signal in accordance with an output of said second comparison unit. 8. A prepit detecting apparatus according to claim 1, wherein said amplitude correction unit incorporates a first amplitude extracting unit for extracting an average amplitude level of the first read signal, a second amplitude extracting unit for extracting an average amplitude level of the second read signal, a first comparison unit for comparing an output of said first amplitude extracting unit with a reference level, a second comparison unit for comparing an output of said second amplitude extracting unit with a reference level, a first amplitude adjustment unit for adjusting the amplitude of the first read signal in accordance with an output of said first comparison unit, and a second adjustment unit for adjusting the amplitude of the second read signal in accordance with an output of said second comparison means. 9. A prepit detecting apparatus arranged to use an optical recording medium which has information recording tracks on which information is recorded, which is wobbled in response to a wobble signal having a predetermined frequency and which has guide tracks for guiding a light beam to said information recording track having prepits for saving pre-information and incorporating a light receptor divided into a first divided light receiving portion and a second divided light receiving portion divided along an optically parallel division line in a direction of tangent of the information tracks and arranged to receive reflected light of the light beam with which the optical recording medium has been irradiated and a difference calculator for calculating the difference between a first read signal output from said first divided light receiving portion and a second read signal output from said second divided light receiving portion so that the prepit is detected in response to a differential signal output from said difference calculator, said prepit detecting apparatus comprising: a DC clamping unit for clamping the differential signal output from said difference calculator with a DC level; and a prepit detector which compares an output from said DC clamping unit and a reference slice level with each other to detect the prepit signal; wherein said DC clamping unit clamps the wobble signal component corresponding to detection timing of the prepit signal detected by said prepit detector to the predetermined DC level. 10. A prepit detecting apparatus according to claim 4, wherein said DC clamping unit incorporates a relay for relaying the differential signal at detection timing of the prepit signal, an integrating circuit for integrating the differential signal supplied through said relay and a superimposing unit for superimposing an output of said integrating circuit on the differential signal, and said integrating circuit incorporates a calculation amplified having a non-inverted input terminal to which a predetermined DC level is input and an integrating capacitor connected between an output terminal of said calculation amplifier and an inverted input terminal.