Wireless communication system, wireless communication apparatus and directivity determination method

What is claimed is: 1. A wireless communication system for adaptively determining a communication directivity when a Signal to Interference plus Noise Ratio (SINR) is not directly measurable, the system comprising: a wireless transmitter, and a wireless receiver, wherein, in a first step, the wireless receiver measures a reception parameter while scanning M pieces of reception directivity during an interval in which a signal is not transmitted from the wireless transmitter, where M is an integer that is equal to or greater than 2, and retains a first result of the measurement which includes interference plus noise, and in a second step, the wireless transmitter transmits a first signal to the wireless receiver while scanning L pieces of transmission directivity, where L is an integer that is equal to or greater than 2, the wireless receiver measures a reception parameter relating to reception of the first signal that is transmitted at each of the L pieces of transmission directivity, determines k pieces of transmission directivity that correspond to high-ranking k results, respectively, of the measurements that have a great reception parameter, and reports the determined k pieces of transmission directivity to the wireless transmitter, where k is a predetermined integer value <L, the wireless transmitter forms any one of the k pieces of transmission directivity and transmits a second signal to the wireless receiver, and the wireless receiver: measures a reception parameter relating to reception of the second signal that is transmitted by the wireless transmitter, while scanning the M pieces of reception directivity, and retains a second result of the measurement which includes both the second signal and the interference plus noise, and calculates an SINR of each of the M pieces of reception directivity based on a comparison between the first result of the measurement obtained in the first step and the second result of the measurement obtained in the second step, and determines a reception directivity having an SINR exceeding a prescribed value, among the M pieces of reception directivity, for use in data communication. 2. The wireless communication system according to claim 1 , wherein the wireless transmitter determines a transmission directivity that corresponds to the reception directivity, which is determined by the wireless receiver, for use in the data communication. 3. The wireless communication system according to claim 1 , wherein the wireless receiver receives the first signal that is transmitted at each of the L pieces of transmission directivity, in a omnidirectional manner. 4. The wireless communication system according to claim 1 , wherein the wireless transmitter forms the k pieces of transmission directivity in an order of pieces of transmission directivity that corresponds to a descending order of the high-ranking k results of the measurement. 5. The wireless communication system according to claim 1 , wherein, the wireless receiver calculates an SINR based on a difference between the first result of the measurement and the second result of the measurement. 6. The wireless communication system according to claim 1 , wherein, responsive to no SINR calculated for each of the M pieces of reception directivity exceeding the prescribed value, the wireless receiver determines a reception directivity having a maximum SINR, among the M pieces of reception directivity, for use in the data communication. 7. The wireless communication system according to claim 1 , wherein transmission sequence processing that determines a transmission directivity which is to be used by the wireless transmitter for the data communication, and reception sequence processing that determines a reception directivity which is to be used by the wireless receiver for the data communication are performed with every transmission periodicity for the data communication. 8. A wireless communication apparatus that is communicatively connected to a wireless transmitter, the wireless communication apparatus comprising: a reception antenna unit that receives a signal which is transmitted from the wireless transmitter; a memory storing instructions; and a processor configured to implement the instructions and execute a plurality of tasks, including: in a first step, a setting task that sets M pieces of reception directivity in the reception antenna unit in a manner that is scannable, where M is an integer that is equal to or greater than 2; a measurement task that measures a reception parameter at each of the M pieces of reception directivity during an interval in which a signal is not transmitted from the wireless transmitter; and a storing task that stores a first result of the measurement of the reception parameter into the memory, wherein the first result of the measurement includes interference plus noise; and in a second step, a reception control task that determines k pieces of transmission directivity which correspond to high-ranking k results, respectively, of the measurements that have a great reception parameter, based on a result of measurement of a reception parameter relating to reception of a first signal that is transmitted while scanning L pieces of transmission directivity from the wireless transmitter, where k is a predetermined integer value and L is an integer that is equal to or greater than 2, wherein the measurement task measures a reception parameter relating to reception of a second signal that is transmitted at any one of the k pieces of transmission directivity from the wireless transmitter while the M pieces of reception directivity are scanned, and stores a second result of the measurement of the reception parameter in the memory, wherein the second result of the measurement includes both the second signal and the interference plus noise, and wherein the reception control task calculates a Signal to Interference plus Noise Ratio (SINR) of each of the M pieces of reception directivity based on a comparison between the first result of the measurement obtained in the first step and the second result of the measurement obtained in the second step, and determines a reception directivity having an SINR exceeding a prescribed value, among the M pieces of reception directivity, for use in data communication. 9. A directivity determination method in a wireless communication system in which a wireless transmitter and a wireless receiver are connected communicatively, the directivity determination method comprising: in a first step, by the wireless receiver, measuring a reception parameter while scanning M pieces of reception directivity during an interval in which a signal is not transmitted from the wireless transmitter, where M is an integer that is equal to or greater than 2, and retaining a first result of the measurement which includes interference plus noise; and in a second step, by the wireless transmitter, transmitting a first signal to the wireless receiver while scanning L pieces of transmission directivity, where L is an integer that is equal to or greater than 2; by the wireless receiver, measuring a reception parameter relating to reception of the first signal that is transmitted at each of the L pieces of transmission directivity, determining k pieces of transmission directivity that correspond to high-ranking k results, respectively, of the measurements that have a great reception parameter, where k is a predetermined integer value <L, and reporting the determined k pieces of transmission directivity to the wireless transmitter; by the wireless transmitter, forming any one of the k pieces of transmission directivity and transmitting a second signal to the wireless receiver; by the wireless receiver, meas