Electronic timepiece, communication device, and communication system

What is claimed is: 1 . An electronic timepiece comprising: a solar cell that receives light and generates power; a detection circuit configured to detect an output value of the solar cell; a storage battery charged by power generated by the solar cell; a charging control circuit configured to connect and disconnect the solar cell and the storage battery; and a control circuit configured to control the detection circuit and the charging control circuit, set a detection period in which the control circuit detects the output value of the solar cell and receives an optical signal, and a charging period in which the storage battery can be charged, during a reception period for receiving a data signal of transmission data transmitted from a communication target, control the charging control circuit to disconnect the solar cell and the storage battery, and cause the detection circuit to detect the output value of the solar cell, during the detection period, and control the charging control circuit to connect the solar cell and the storage battery during the charging period. 2 . The electronic timepiece described in claim 1 , further comprising: a transmission coil, and a coil drive circuit configured to drive the transmission coil; wherein the control circuit controls the coil drive circuit to transmit a data request signal requesting transmission of the data signal by electromagnetic coupling, and the reception period is a period after the data request signal is transmitted and until the next data request signal is transmitted. 3 . The electronic timepiece described in claim 1 , further comprising: the data signal is transmitted one bit at a time from the communication target; and the control circuit sets the detection period and the charging period in each reception period receiving the data signal of one bit. 4 . The electronic timepiece described in claim 1 , further comprising: a data signal storage configured to store the received data signal; wherein each time one block of data signals is received, the control circuit stores the received one block of data signals, and controls the charging control circuit to connect the solar cell and the storage battery while storing the one block of data signals to the data signal storage. 5 . The electronic timepiece described in claim 1 , further comprising: a data signal storage configured to store the received data signal; wherein each time one block of data signals is received, the control circuit stores the received one block of data signals, and controls the charging control circuit to connect the solar cell and the storage battery during a specific time before or after storing the one block of data signals to the data signal storage. 6 . The electronic timepiece described in claim 1 , further comprising: a battery voltage detection circuit configured to detect the battery voltage of the storage battery; wherein if the value detected by the battery voltage detection circuit is greater than or equal to a threshold in the charging period, the control circuit controls the charging control circuit to disconnect the solar cell and the storage battery. 7 . The electronic timepiece described in claim 1 , further comprising: a battery voltage detection circuit configured to detect the battery voltage of the storage battery; wherein the control circuit sets the length of the reception period and the charging period according to the value detected by the battery voltage detection circuit. 8 . A communication device comprising: a light-emitting device configured to emit light; a light-emitting device drive circuit configured to drive the light-emitting device; and a device-side transmission controller configured to control the light-emitting device drive circuit and transmit the data signal by light by changing the emission state of the light-emitting device according to the value of the data signal of the transmission data, the device-side transmission controller maintaining the emission state of the light-emitting device in the state corresponding to the value of the data signal during the transmission period allocated to the data signal. 9 . The communication device described in claim 8 , wherein: a first signal and a second signal of different values are included in the data signals; and the device-side transmission controller causes the light-emitting device to emit when the data signal is the first signal, and turns the light-emitting device off when the data signal is the second signal. 10 . The communication device described in claim 8 , wherein: a first signal and a second signal of different values are included in the data signals; and the device-side transmission controller causes the light-emitting device to emit at a first luminance level when the data signal is the first signal, and causes the light-emitting device to emit at a second luminance level that is lower than the first luminance level when the data signal is the second signal. 11 . The communication device described in claim 8 , further comprising: an emission controller configured to control the light-emitting device drive circuit to cause the light-emitting device to emit after data signals for all transmission data is transmitted. 12 . The communication device described in claim 8 , further comprising: an emission controller configured to control the light-emitting device drive circuit to cause the light-emitting device to emit before transmission of the transmission data starts. 13 . A communication system comprising an electronic timepiece and a communication device; the electronic timepiece including a solar cell that receives light and generates power; a detection circuit configured to detect an output value of the solar cell; a storage battery charged by power generated by the solar cell; a charging control circuit configured to connect and disconnect the solar cell and the storage battery; and a control circuit configured to control the detection circuit and the charging control circuit, set a detection period in which the control circuit detects the output value of the solar cell and receives an optical signal, and a charging period in which the storage battery can be charged, during a reception period for receiving a data signal of transmission data transmitted from a communication device, control the charging control circuit to disconnect the solar cell and the storage battery, and cause the detection circuit to detect the output value of the solar cell, during the detection period, and control the charging control circuit to connect the solar cell and the storage battery during the charging period; and the communication device including a light-emitting device configured to emit light; a light-emitting device drive circuit configured to drive the light-emitting device; and a device-side transmission controller configured to control the light-emitting device drive circuit and transmit the data signal by light by changing the emission state of the light-emitting device according to the value of the data signal of the transmission data, the device-side transmission controller maintaining the emission state of the light-emitting device in the state corresponding to the value of the data signal during a period in the reception period that includes the detection period and is longer than the detection period. 14 . The communication system described in claim 13 , wherein: a first signal and a second signal of different values are included as the data signals in the transmission data; and the device-side transmissio