Capacitive micromachined ultrasonic transducer and ultrasonic imaging apparatus

The invention claimed is: 1. A capacitive micromachined ultrasonic transducer comprising: a plurality of non-blocked and blocked cells which are arranged in two dimensions as a cell array, where each non-blocked cell includes a floor portion, a wall portion, a membrane portion opposed to the floor portion and supported by the wall portion, a floor electrode provided in the floor portion and a membrane electrode provided in the membrane portion, and where each blocked cell includes a floor portion, a wall portion, a membrane portion opposed to the floor portion and supported by the wall portion; a circuit-based signal processor configured to process signals by the cells; and a signal blocker, provided for each blocked cell in the blocked cell group located in edge portions of the cell array, where the signal blocker is in a form of at least one of: a displacement-inhibiting material made of a gas, liquid, or solid filling a cell void of the blocked cell; an incomplete electrical conduction path in a form of a cut line or switch provided between the blocked cell and the circuit-based signal processor; each blocked cell having only one of a floor electrode or a membrane electrode; each blocked cell having no electrodes; a signal inhibiting circuit in a conduction path between the blocked cell and the circuit-based signal processor; an openable and closeable switch; where the signal blocker is configured to permanently block a conveying of signals between the circuit-based signal processor and the blocked cell group located in the edge portions of the cell array, wherein the non-blocked cells do not include the signal blocker. 2. The capacitive micromachined ultrasonic transducer according to claim 1 , wherein: the signal inhibiting circuit as the signal blocker, is configured to block the transmission of signals between the circuit-based signal processor and the blocked cell group, when a direct-current bias voltage is applied to the first electrode. 3. The capacitive micromachined ultrasonic transducer according to claim 1 , wherein: the floor electrode is formed as a single floor electrode commonly shared by the plurality of non-blocked and blocked cells having the floor electrode; and the membrane electrode for each of the plurality of non-blocked and blocked cells having the membrane electrode is formed as a separate electrode. 4. An ultrasonic imaging apparatus comprising: an ultrasonic probe configured to transmit ultrasound waves to a test subject, and to receive echo signals reflected by the test subject; a transmission-beam former configured to supply the ultrasonic probe with transmission-beam signals so as to transmit the transmission-beam signals to the test subject; a reception-beam former configured to perform signal processing in which echo signals received from the test subject are converted into reception-beam signals; an image processor configured to perform image processing on the reception-beam signals resulting from the signal processing, the image processing including filtering, an envelope signal detection, and processing using a scan converter; and an image displayer configured to display an ultrasonic image based on the reception-beam signals resulting from the image processing, wherein the ultrasonic probe is a capacitive micromachined ultrasonic transducer described in claim 1 . 5. The capacitive micromachined ultrasonic transducer according to claim 4 , wherein: the signal inhibiting circuit as the signal blocker, is configured to block the transmission of signals between the circuit-based signal processor and the blocked cell group, when a direct-current bias voltage is applied to the first electrode. 6. The capacitive micromachined ultrasonic transducer according to claim 4 , wherein: the floor electrode is formed as a single floor electrode commonly shared by the plurality of non-blocked and blocked cells having the floor electrode; and the membrane electrode for each of the plurality of non-blocked and blocked cells having the membrane electrode is formed as separate electrode. 7. A capacitive micromachined ultrasonic transducer comprising: a plurality of first cells which are arranged in two dimensions as a cell array, where each first cell includes a floor portion, a wall portion, a membrane portion opposed to the floor portion and supported by the wall portion, a floor electrode provided in the floor portion, and a membrane electrode provided in the membrane portion; a plurality of second cells which are located surrounding the cell array, where each second cell includes a floor portion, a wall portion, and a membrane portion opposed to the floor portion and supported by the wall portion; and a circuit-based signal processor constructed at least in part of hardware and configured to process signals by the first cells, wherein: at least one of the circuit-based signal processor and the plurality of second cells, are constructed to permanently prevent the circuit-based signal processor from considering signals from the plurality of second cells, wherein the circuit-based signal processor is prevented from considering signals from the plurality of second cells via at least one of: an incomplete electrical conduction path in a form of a cut line or a switch provided between the blocked cell and the circuit-based signal processor; a signal inhibiting circuit in a conduction path between the blocked cell and the circuit-based signal processor; an openable and closeable switch, a displacement-inhibiting material made of a gas, liquid, or solid filling a cell void of each cell of the second cells; each of the plurality of second cells having only one of a floor electrode and a membrane electrode; and each of the plurality of second cells having no electrodes, wherein the non-blocked cells do not include the signal blocker. 8. An ultrasonic imaging apparatus comprising: an ultrasonic probe configured to transmit ultrasound waves to a test subject and to receive echo signals reflected by the test subject; a transmission-beam former configured to supply the ultrasonic probe with transmission-beam signals so as to transmit the transmission-beam signals to the test subject; a reception-beam former configured to perform a signal processing in which echo signals received from the test subject are converted into reception-beam signals; an image processor configured to perform image processing on the reception-beam signals resulting from the signal processing, the image processing including filtering, an envelope signal detection, and processing using a scan converter; and an image displayer configured to display an ultrasonic image based on the reception-beam signals resulting from the image processing, wherein the ultrasonic probe is a capacitive micromachined ultrasonic transducer described in claim 7 . 9. A capacitive micromachined ultrasonic transducer comprising: a plurality of cells and peripheral cells which are arranged in two dimensions as a cell array, where each cell includes a floor portion, a wall portion, a membrane portion opposed to the floor portion and supported by the wall portion, a first electrode provided in the floor portion, and a second electrode provided in the membrane portion, and where each peripheral cell includes a floor portion, a wall portion, a membrane portion opposed to the floor portion and supported by the wall portion; a circuit-based signal processor constructed at least in part of hardware and configured to control transmission and reception of signals by the cells; and wherein at least one of the circuit-based signal processor and the peripheral cells of the cell array, are constructed to permanently prevent the circuit-based signal processor from c