Transmission circuit

What is claimed is: 1. A transmission circuit configured to connect to a transmission line and to transmit a differential signal, the transmission circuit comprising: a first transmitter configured to transmit the differential signal to the transmission line by switching between a drive state for supplying an electric power to the transmission line and a non-drive state for interrupting a supply of the electric power to the transmission line, according to a binary-represented transmission signal received by the first transmitter; and a second transmitter configured to transmit the differential signal to the transmission line by switching between a drive state for supplying an electric power to the transmission line and a non-drive state for interrupting a supply of the electric power to the transmission line, according to the binary-represented transmission signal and a permission signal received by the second transmitter, wherein the non-drive state of the second transmitter occurs in a dominant period when the first transmitter is in the drive state, and the drive state of the second transmitter occurs in a recessive period when the first transmitter is in the non-drive state, and wherein the second transmitter switching between the drive state and the non-drive state outputs the differential signal in the recessive period with a smaller amplitude and a reverse polarity relative to an amplitude and a polarity of the differential signal output in the dominant period. 2. The transmission circuit of claim 1 , wherein the transmission signal and the permission signal received by the transmission circuit are transmitted in a low-speed field and a high-speed field, and wherein the second transmitter is configured to transmit the differential signal when the transmission signal and the permission signal are transmitted in the high-speed field, and wherein a portion of the transmission signal transmitted in the low-speed field is transmitted at a predetermined speed, and wherein a portion of the transmission signal transmitted in the high-speed field is transmitted at a speed higher than the predetermined speed. 3. The transmission circuit of claim 2 , wherein the differential signal has a voltage level, the voltage level of the differential signal comparable against a reception threshold voltage to determine a signal level of the differential signal, wherein the reception threshold voltage is a midpoint of a differential signal waveform output when the transmission signal is transmitted in the high-speed field. 4. The transmission circuit of claim 2 , wherein the transmission signal received by the transmission circuit is transmitted according to a Controller Area Network with Flexible Date rate (CAN-FD) protocol, and wherein a portion of the transmission signal designated as an arbitration field signal is transmitted in the low-speed field, and wherein a portion of the transmission signal designated as a non-arbitration field signal is transmitted in the high-speed field. 5. The transmission circuit of claim 1 , wherein the transmission line includes a first signal line and a second signal line, and wherein the transmission signal received by the transmission circuit has a first signal level and a second signal level, and wherein the first transmitter includes: a first switch connected at a position between a preset first potential and the first signal line; a second switch connected at a position between a preset second potential and the second signal line, wherein the second potential is less than the first potential; and a first driver circuit configured to control the first switch and the second switch when the transmission signal is in the first signal level, and wherein the second transmitter includes: a third switch connected at a position between the preset first potential and the second signal line; a fourth switch connected at a position between the preset second potential and the first signal line; a second driver circuit configured to control the third switch and the fourth switch when the transmission signal is in the second signal level; and an amplitude suppressor configured to suppress the differential signal transmitted from the second transmitter. 6. The transmission circuit of claim 5 , wherein the amplitude suppressor is a diode, and wherein a diode is connected in series to each of the third switch and the fourth switch. 7. A transceiver comprising: a transmission circuit configured to transmit a differential signal, the transmission circuit including a first transmitter configured to transmit the differential signal to the transmission line by switching between a drive state for supplying an electric power to the transmission line and a non-drive state for interrupting a supply of the electric power to the transmission line, according to a binary-represented transmission signal received by the first transmitter, and a second transmitter configured to transmit the differential signal to the transmission line by switching between a drive state for supplying an electric power to the transmission line and a non-drive state for interrupting a supply of the electric power to the transmission line, according to the binary-represented transmission signal and a permission signal received by the second transmitter; and a reception circuit configured to receive the differential signal from the transmission line, wherein the non-drive state of the second transmitter occurs in a dominant period when the first transmitter is in the drive state, and the drive state of the second transmitter occurs in a recessive period when the first transmitter is in the non-drive state, and wherein the second transmitter switching between the drive state and the non-drive state outputs the differential signal in the recessive period with a smaller amplitude and a reverse polarity relative to an amplitude and a polarity of the differential signal output in the dominant period.