Reverse current detector circuit

What is claimed is: 1. A reverse current detector circuit for a DCDC converter, the reverse current detector circuit comprising: a sensing input connected to a reverse-current sensing node of the DCDC converter; a timing control output of a timing control circuit arranged for controlling a current-flow sequence timing of the DCDC converter; a flip-flop circuit providing to the timing control circuit the direction of a residual current at said reverse-current sensing node; a logic gate having a gate output connected to a data input of the flip-flop circuit; a first gate input connected to the sensing input; a second gate input receiving an input gating signal; a first timing control input receiving a first timing control signal of the DCDC converter; a first delay means for providing a first delayed timing signal by delaying the first timing control signal by a first delay period; an up-down counter forming said timing control circuit, wherein the logic gate is configured and connected such that, while the input gating signal has a first logic value, the logic state of the gate output depends on the first gate input and, when the input gating signal has a second logic value, a logic gate circuit is in a powered-down state such that the logic state of the gate output is independent of the first gate input, and wherein the up-down counter is clocked by the first delayed timing signal to increment a count value if the gate output is in a first gate output logic state when the up-down counter is clocked by the first delayed timing signal changing to a first clocking logic state, and to decrement the count value if the gate output is in a second gate output logic state when the up-down counter is clocked by the first delayed timing signal changing to the first clocking logic state. 2. The reverse current detector circuit according to claim 1 , wherein the up-down counter is configured to enter a powered-down state when the first delayed timing signal has a second clocking logic state. 3. The reverse current detector circuit according to claim 1 , wherein the input gating signal is the first delayed timing signal. 4. The reverse current detector circuit according to claim 1 , wherein the up-down counter comprises count-override means for detecting a convergence condition of the reverse current detector circuit and for putting the up-down counter in a powered-down mode for a predetermined time period. 5. The reverse current detector circuit according to claim 4 , wherein the convergence condition comprises an increment-decrement-increment or a decrement-increment-increment sequence of the up-down counter. 6. The reverse current detector circuit according to claim 1 , further comprising: a second delay means for generating a second delayed timing signal by delaying the first timing control signal by a second delay period which is shorter than the first delay period. 7. The reverse current detector circuit according to claim 1 , wherein the logic gate is formed by an AND gate. 8. The reverse current detector circuit according to claim 1 , wherein said timing control circuit comprises the output timing control circuit configured to generate an output timing control signal for controlling a second phase timing of the DCDC converter, the output timing control signal having a control period which is dependent on the count value. 9. The reverse current detector circuit according to claim 1 , wherein the flip-flop circuit is arranged to store the gate output during a second delay period, under the control of a second delayed timing signal, and wherein the up-down counter is clocked by the first delayed timing signal to increment the count value if the flip-flop circuit output is in the first gate output logic state when the up-down counter is clocked, and to decrement the count value if a latched gate output is in the second gate output logic state when the up-down counter is clocked. 10. The reverse current detector circuit according to claim 8 , wherein the output timing control circuit comprises an analog delay cell. 11. The reverse current detector circuit according to claim 8 , wherein the output timing control circuit receives an output circuit control signal, and wherein the output timing control circuit is configured to, when the output circuit control signal is in a predetermined logic state, enter a powered-down state. 12. The reverse current detector circuit according to claim 11 , wherein the output circuit control signal is a second timing control signal of the DCDC converter. 13. A DCDC converter comprising: a reverse current detector circuit according to claim 1 , a reactive element, a first switching element controlled by the first timing control signal with a second phase timing, and a second switching element controlled by a second timing control signal with a first phase timing, wherein the second phase timing is controlled by the output timing control circuit, and wherein the second timing control signal is an output circuit control signal. 14. A DCDC converter comprising: a reverse current detector circuit according to claim 7 , a reactive element, a first switching element controlled by the first timing control signal with a second phase timing, and a second switching element controlled by a second timing control signal with a first phase timing, wherein the second phase timing is controlled by the output timing control circuit, and wherein the second timing control signal is an output circuit control signal. 15. A reverse current detector circuit for a DCDC converter, the reverse current detector circuit comprising: a sensing input connected to a reverse-current sensing node of the DCDC converter; a timing control output of a timing control circuit configured to control a current-flow sequence timing of the DCDC converter; a flip-flop circuit providing to the timing control circuit the direction of a residual current at said reverse-current sensing node; a logic gate having a gate output connected to a data input of the flip-flop circuit; a first gate input connected to the sensing input; a second gate input receiving an input gating signal; a first timing control input receiving a first timing control signal of the DCDC converter; a first delay circuit configured to provide a first delayed timing signal by delaying the first timing control signal by a first delay period; an up-down counter forming said timing control circuit, wherein the logic gate is configured and connected such that, while the input gating signal has a first logic value, the logic state of the gate output depends on the first gate input and, when the input gating signal has a second logic value, a logic gate circuit is in a powered-down state such that the logic state of the gate output is independent of the first gate input, and wherein the up-down counter is clocked by the first delayed timing signal to increment a count value if the gate output is in a first gate output logic state when the up-down counter is clocked by the first delayed timing signal changing to a first clocking logic state, and to decrement the count value if the gate output is in a second gate output logic state when the up-down counter is clocked by the first delayed timing signal changing to the first clocking logic state.