High-efficiency, dual current sink laser diode driver
Abstract
Provided are assemblies and processes for activating light emitting devices. A first current sink is in electrical communication with a common source through a current node and configured to draw a first current through the current node in response to a respective control signal. A second current sink is also provided in electrical communication with the current node and in parallel with the first current sink, also configured to draw a second current through the current node in response to a respective control signal. An aggregate current is drawn through the array, determined as a combination of the first and second currents. A commanded current from the first current sink can be shunted around the second array and the second current sink, providing a capability to series both the first and second laser diode light-emitting arrays, while simultaneously drawing different current amplitudes through each array from a common potential source.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A multi-stage laser drive circuit configured to draw current from a common potential source, comprising:
a current node; a first light-emitting array in electrical communication between the common potential source and the current node; a first current sink in electrical communication with the current node, the first current sink having a first control terminal and configured to draw a first current from the common potential source, through the current node in response to a respective current control output signal received at the first control terminal; and a second current sink in electrical communication with the current node and in a parallel arrangement with respect to the first current sink, the second current sink having a second control terminal and configured to draw a second current from the common potential source, through the current node in response to a respective current control output signal received at the second control terminal, whereby an aggregate current drawn through the first light-emitting array is determined substantially by a combination of the first and second currents, the first light-emitting array configured to emit light in response to current drawn therethrough.
2 . The multi-stage laser drive circuit of claim 1 , further comprising at least one current-drive circuit having a current-enable input, a current-level setting input and a current control output in electrical communication with one of the first and second control terminals, the current-drive circuit configured to selectively provide a respective current control output signal in response to a signal received at the current-enable input, the respective current control output signal, when provided, being further determined by a signal received at the current-level setting input.
3 . The multi-stage laser drive circuit of claim 1 , further comprising a second light-emitting array in electrical communication with the first current sink, such that current drawn through the second light-emitting array is substantially determined by the second current, the second light-emitting array optical output adapted to pump up the gain medium, which, in turn, is configured to emit light in response to current drawn through said second light-emitting array comprising at least one light-emitting device.
4 . The multi-stage laser drive circuit of claim 3 , wherein at least one said light-emitting device comprises an optical pumping source.
5 . The multi-stage laser drive circuit of claim 3 , wherein at least one said light-emitting device comprises a Laser diode.
6 . The multi-stage laser drive circuit of claim 3 , wherein at least one of the first and second current sinks comprises a semiconductor device.
7 . The multi-stage laser drive circuit of claim 6 , wherein the semiconductor device is a metal-oxide-semiconductor field effect transistor (MOSFET) device.
8 . The multi-stage laser drive circuit of claim 3 , further comprising at least one current-drive circuit having a current-enable input, a current-level setting input and a current control output in electrical communication with one of the first and second control terminals, the current-drive circuit configured to selectively provide a respective current control output signal in response to a signal received at the current-enable input, the respective current control output signal, when provided, being further determined by a signal received at the current-level setting input.
9 . The multi-stage laser drive circuit of claim 8 , further comprising a controller in electrical communication with the current-enable and current-level setting inputs of the at least one current drive circuit, the controller configured to provide a current-enable signal to the current-enable input and a current-level setting signal to the current-level setting input.
10 . The multi-stage laser drive circuit of claim 9 , further comprising at least one current sensing device in electrical communication with a respective one of the first and second current sinks and with the controller, the current sensing device configured to provide a respective output signal indicative of a respective current drawn therethrough.
11 . A method for driving a first light-emitting array, comprising:
receiving first and second current control signals; drawing a first current from a common potential source through a current node in response to the received first current control signal; drawing a second current from the common potential source through the current node in response to the received second current control signal, the first and second currents being in parallel with respect to each other; and drawing an aggregate current through a first light-emitting array, the aggregate current determined substantially by a combination of the first and second currents, wherein the light-emitting array emits light in response to the aggregate current drawn there through.
12 . The method of claim 11 , further comprising:
receiving a current-enable signal comprising at least two states corresponding to active and standby; receiving a current-level setting signal; determining at least one of the first and second current control signals in response to the received current-enable and current-level setting signals, the respective one of the first and second currents being selectively drawn responsive to the current-enable signal being in the active state.
13 . The method of claim 11 , further comprising emitting light from a second light-emitting array in response to the first current.
14 . The method of claim 13 , further comprising:
receiving a current-enable signal comprising at least two states corresponding to active and standby; receiving a current-level setting signal; determining at least one of the first and second current control signals in response to the received current-enable and current-level setting signals, the respective one of the first and second currents being selectively drawn responsive to the current-enable signal being in the active state.
15 . The method of claim 14 , further comprising pumping a laser gain medium by light emitted from at least one said light-emitting arrays.
16 . The method of claim 14 , wherein the received current-level setting signal varies while the current-enable signal is in the active state.
17 . The method of claim 16 , wherein the current-level setting signal comprises a momentary peak configured to induce a momentary peak output of at least one said series connected, light-emitting arrays adapted to optically excite the gain medium being pumped, thereby providing synchronization in the optical excitation with respect to the laser output.
18 . A Master Oscillator Power Amplifier (MOPA) laser optical pumping system, comprising:
means for receiving first and second current control signals; means for drawing a first current from a common potential source through a current node in response to the received first current control signal; means for drawing a second current from the common potential source through the current node in response to the received second current control signal, the first and second currents in parallel with respect to each other; means for drawing an aggregate current through a first light-emitting array, the aggregate current determined substantially by a combination of the first and second currents, wherein the first light-emitting array emits light in response to the aggregate current drawn there through; and means for emitting first pump light in response to the aggregate current; and means for communicating first pump light into a power amplifier (PA) gain medium.
19 . The MOPA laser optical pumping system of claim 18 , further comprising:
means for drawing a second current through a second light-emitting array, wherein the second light emitting array emits light in response to the current drawn therethrough, the second current being less than or equal to the aggregate current through the first light-emitting array by an amount equal to the first current, which is shunted around the second current and second light-emitting array, wherein the second current through the second light emitting array offers a means for communicating second pump light into a master oscillator (MO) gain medium.Join the waitlist — get patent alerts
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