The invention relates to the field of charge pumps. In particular, the invention relates to charge pumps for Ultra High Frequency Radio Frequency IDentification Integrated Circuits (UHF-RFID-IC).
UHF-RFID-ICs generally needs a power source for operation. The power source usually comprises a so-called charge pump or voltage multiplier boosting a low voltage power supply. One requirement for the power supply is generally that DC levels are blocked, so that the RFID-IC suffers no malfunction due to a possible DC level. This is in particular the case since UHF-RFID-ICs are operated with a loop antenna. In general the blocking is done by providing a series capacity in the RF branch of the RFID-IC.
A standard voltage multiplier or charge pump is schematically shown in
A second input node 410 is coupled to a second circuit node 411 which is coupled to a second output node 412 which is connected to ground. Further, the second circuit node 411 is coupled to an anode 413 of a second diode 414. A cathode 415 of the second diode 414 is coupled to the first circuit node 405. The second input node 410 and the second circuit node 411, and the second output node 412 form a second branch of the charge pump, the so-called lower-branch.
In operation of the charge pump 400 an alternating current or voltage can be applied to the first input node 401 and the second input node 411. That is a voltage difference of Ue exists between the both input nodes. Further, a voltage drop of Uf occurs over the second diode 414 which corresponds to the so-called forward voltage of the diode. Thus, the capacity in the RF-branch is charged with a voltage Ues−Uf, wherein Uef represent the peak value of the alternating voltage Ue. In operation this voltage the capacity is charged with is added to the peak value Uef, thus leading to a “multiplied” voltage, while the forward voltage of the diode is lost.
The total voltage of the charge pump 400 which is provided between the first output 407 node and the second output node 413 is
U
Q
=Û
e+(Ûe−Uf)−UfUQ=2Ûe−2Uf.
Furthermore, in
Furthermore, a storage capacity, or so-called smoothing capacity, 416 and a resistive load 417 are schematically shown in
A low power charge pumped DC bias supply similar to the one shown in
An exemplary embodiment of the invention provides a charge pump stage comprises a first input node, a second input node, a decoupling capacity having a first terminal and a second terminal. Further, the charge pump stage comprises a pump control circuit having a first contact node and a second contact node, wherein the first input node is coupled to the first contact node. Furthermore, the second input node is coupled to the first terminal of the decoupling capacity, and the second terminal of the decoupling capacity is coupled to the second contact node and further coupled to ground.
A characteristic feature according to the present invention may be that a decoupling capacitance of a charge pump according to the present invention is coupled into the so-called lower branch, i.e. the branch which is coupled to ground, instead of coupling it into the RF-branch as it is in charge pumps according to the known state of the art. Thus, the decoupling capacitance, also called first capacity, may be coupled directly to ground. This kind of coupling may lead to the fact that unavoidable parasitic capacities of the charge pump are added to the implemented capacity, i.e. the decoupling capacity. Thus, these capacities may now be useful since the decoupling capacity can be designed smaller. Further, it might be possible that the matching of the antenna circuitry is getting easier when a charge pump according to the present invention is used. Furthermore, it might be possible that the effect of the parasitic capacities on the efficiency of the voltage multiplier is reduced, when a charge pump according to the present invention is used.
Furthermore, the so-called Q-factor, i.e. the figure of merit, of the decoupling capacity, also called series capacity, has a big influence on the efficiency of the charge pump. The Q-factor can be calculated as Q=Xc/Rs, wherein Xc is the series reactance and Rs is the series resistance of the capacity. In general there is always a trade off between parasitic capacity and series resistance in order to achieve a good Q-factor. Since the parasitic capacity may be added to the implemented decoupling capacity in a charge pump according to present invention this trade off may not be a hard limit anymore.
Referring to the dependent claims, further preferred embodiments of the invention will be described in the following.
Next, preferred exemplary embodiments of the charge pump stage of the invention will be described. These embodiments may also be applied for a multi-stage charge pump.
In another exemplary embodiment the pump control circuit of the charge pump stage further comprises a third contact node and a fourth contact node which are adapted to form a first output node and a second output node.
In a further exemplary embodiment the pump control circuit further comprises a first diode, coupled between the first contact node and the second contact node.
In yet another exemplary embodiment the pump control circuit further comprises a second diode.
In still another exemplary embodiment of the charge pump stage the second diode is coupled between the first contact node and the third contact node.
In an exemplary embodiment a multi-stage charge pump comprising a plurality of charge pump stages, wherein at least one charge pump stage is formed according to an charge pump stage according to the present invention.
In another exemplary embodiment the multi-stage charge pump further comprising a switching element, which is coupled between different stages of the plurality of charge pump stages.
In yet another exemplary embodiment of the multi-stage charge pump the switching element is coupled into the multi-stage charge pump in such a way that a supply voltage provided by the charge pump is not multiplied.
In yet still another exemplary embodiment of the multi-stage charge pump the switching element comprises a transistor and/or a MOS-diode.
In an exemplary embodiment an RFID-tag comprises at least one charge pump stage according to the present invention or comprises a multi-stage charge pump according to the present invention.
The present invention may be of particular interest in the field of RFID tags, since it may provide an effective power source for an RFID tag.
A characteristic feature according to the present invention may be that while according to the prior art a decoupling capacity is coupled into the RF-branch of a charge pump, i.e. the branch having a high voltage level, the decoupling capacity of a charge pump according to the present invention is shifted into the lower branch, i.e. the branch having a low voltage level and/or is coupled directly to ground potential, instead. Therefore, one terminal of the decoupling capacity may be coupled directly to ground, i.e. to ground potential. Thus, unavoidable parasitic capacities, generated by the charge pump circuit with respect to ground are added to the implemented decoupling capacity. Thus, these capacities may now be useful since the decoupling capacity may be designed smaller and the Q-factor of the decoupling capacity may be increased without the limitation of the trade off between the parasitic capacity of the pump circuit and the series resistance of the decoupling capacity. The input nodes of the charge pump stage or the multi-stage charge pump according to the present invention may be coupled to a loop antenna. This may in particular advantageous if the charge pump is used in connection with an RFID-tag.
The aspects defined above and further aspects of the invention are apparent from the examples of embodiment to be described hereinafter and are explained with reference to the examples of embodiment.
The invention will be described in more detail hereinafter with reference to examples of embodiment but to which the invention is not limited.
The illustration in the drawing is schematically. In different drawings, similar or identical elements are provided with the same or similar reference signs.
In the following, referring to
A second input node 107 is coupled to a first terminal 108 of a capacity 109, which forms a decoupling capacity of the charge pump 100. A second terminal 110 of the capacity 109 is coupled to a second circuit node 111, which is coupled to a second output node 112 and further coupled to ground. Thus, the second terminal 110 of the capacity 109 is directly coupled to ground potential. Further the second circuit node 111 is coupled to an anode 113 of a second diode 114. A cathode 115 of the second diode 114 is coupled to the first circuit node 102. The second input node 107, the capacity 109, and the second circuit node 111, and the second output node 112 form a second branch of the charge pump, the so-called lower-branch. Additionally in
In operation of the charge pump 100 an alternating current or voltage can be applied to the first input node 101 and the second input node 107. That is a voltage difference of Ue exists between the both input nodes. Further, a voltage drop of Uf occurs over the second diode 113 which voltage drop corresponds to the so-called forward voltage of the diode. Thus, the capacity in the lower-branch is charged with a voltage Ues−Uf, wherein Uef represent the peak value of the alternating voltage Ue. In operation this voltage, the capacity is charged with, is added to the peak value Uef, thus leading to a “multiplied” voltage.
The total voltage of the charge pump 100 which is provided between the first output 106 node and the second output node 113 is
U
Q
=Û
e+(Ûe−Uf)−UfUQ=2Ue−2Uf.
Furthermore, in
In the following, referring to
A second input node 207 is coupled to a first terminal 208 of a capacity 209, which forms a decoupling capacity of the multi-stage charge pump 200. A second terminal 210 of the capacity 209 is coupled to a second circuit node 211, which is coupled to ground. Further the second circuit node 211 is coupled to an anode 213 of a second diode 214. A cathode 215 of the second diode 214 is coupled to the first circuit node 202. The second input node 207, the capacity 209, and the second circuit node 211, form the so-called lower-branch of the charge pump 200.
The above described elements of the multi-stage charge pump 200 form a first stage of the multi-stage charge pump.
The third circuit node 216 is coupled to a sixth circuit node 219 which is coupled to a first terminal 220 of a second capacity 221. A second terminal 222 of the second capacity 221 is coupled to a seventh circuit node 223, which is coupled to an anode 224 of a third diode 225. A cathode 226 of the third diode 225 is coupled to an eighth circuit node 227 which is coupled to a second output node 228.
The fourth circuit node 217 is further coupled to an anode 229 of a fourth diode 230. A cathode 231 of the fourth diode 230 is coupled to the seventh circuit node 223.
The elements of the multi-stage charge pump 200 described in the last two paragraphs form a second stage of the multi-stage charge pump.
The sixth circuit node 216 is coupled to a ninth circuit node 232 which is coupled to a first terminal 233 of a third capacity 234. A second terminal 235 of the third capacity 234 is coupled to a tenth circuit node 236, which is coupled to an anode 237 of a fifth diode 238. A cathode 239 of the fifth diode 238 is coupled to an eleventh circuit node 240 which is coupled to a third output node 241.
The eight circuit node 227 is further coupled to an anode 242 of a sixth diode 243. A cathode 244 of the sixth diode 243 is coupled to the tenth circuit node 236.
The elements of the multi-stage charge pump 200 described in the last two paragraphs form a third stage of the multi-stage charge pump.
The ninth circuit node 232 is coupled to a twelfth circuit node 245 which is coupled to a first terminal 246 of a fourth capacity 247. A second terminal 248 of the fourth capacity 247 is coupled to a thirteenth circuit node 249, which is coupled to an anode 250 of a seventh diode 251. A cathode 252 of the seventh diode 251 is coupled to an fourteenth circuit node 253 which is coupled to a fourth output node 254.
The eleventh circuit node 240 is further coupled to an anode 255 of an eighth diode 256. A cathode 257 of the eighth diode 256 is coupled to the thirteenth circuit node 249.
The elements of the multi-stage charge pump 200 described in the last two paragraphs form a fourth stage of the multi-stage charge pump.
The twelfth circuit node 245 is coupled to a fifteenth circuit node 258 which is coupled to a first terminal 259 of a fifth capacity 260. A second terminal 261 of the fifth capacity 260 is coupled to a sixteenth circuit node 262, which is coupled to an anode 263 of a ninth diode 264. A cathode 265 of the ninth diode 264 is coupled to an seventeenth circuit node 266 which is coupled to a fifth output node 267.
The fourteenth circuit node 253 is further coupled to an anode 268 of a tenth diode 269. A cathode 270 of the tenth diode 269 is coupled to the sixteenth circuit node 262.
The elements of the multi-stage charge pump 200 described in the last two paragraphs form a fifth stage of the multi-stage charge pump.
The fifteenth circuit node 258 is coupled to a first terminal 271 of a sixth capacity 272, A second terminal 273 of the sixth capacity 272 is coupled to an eighteenth circuit node 288, which is coupled to an anode 274 of an eleventh diode 275. A cathode 276 of the eleventh diode 275 is coupled to a nineteenth circuit node 277 which is coupled to a twentieth circuit node 278 which is coupled to a sixth output node 279. The twentieth circuit node 278 is further coupled to a twenty first circuit node 280 which is coupled to a first source/drain electrode 281 of a first transistor 282. A second source/drain electrode 283 of the first transistor 282 is coupled to the fifth circuit node 218. The twenty first circuit node 280 is further coupled to a gate 284 of the first transistor 282. Using this coupling the first transistor 282 is operated as a so-called MOS-diode.
The seventeenth circuit node 266 is further coupled to an anode 285 of a twelfth diode 286. A cathode 287 of the twelfth diode 286 is coupled to the eighteenth circuit node 288.
The elements of the multi-stage charge pump 200 described in the last two paragraphs form a sixth stage of the multi-stage charge pump.
In operation of the multi-stage charge pump 200 an alternating current or voltage can be applied to the first input node 201 and the second input node 207. That is a voltage difference of Ue exists between the both input nodes. Accordingly, a voltage having substantially the value of 2*Ue (not considered the forward voltage of the diodes) is provided at the first output node 206. A voltage having substantially the value of 3*Ue is provided at the second output node 228. A voltage having substantially the value of 4*Ue is provided at the third output node 241. A voltage having substantially the value of 5*Ue is provided at the fourth output node 254. A voltage having substantially the value of 6*Ue is provided at the fifth output node 267. A voltage having substantially the value of 7*Ue is provided at the sixth output node 279.
Furthermore, the multi-stage charge pump 200 comprises several storage capacities which are coupled to respective charge pump stages of the multi-stage charge pump 200. A first storage capacity 289 is coupled to the first output node 206. A second storage capacity 290 is coupled to the second output node 228. A third storage capacity 291 is coupled to the third output node 241. A fourth storage capacity 292 is coupled to the fourth output node 254. A fifth storage capacity 293 is coupled to the fifth output node 267 and a sixth storage capacity 294 is coupled to the sixth output node 279.
Using these output voltages of the multi-stage charge pump 200, for example, an RFID-tag can be supplied with power. A system of the multi-stage charge pump according to the present invention and an RFID-tag is schematically shown in
The multi-stage charge pump according to the present invention may be used as a power supply for a common RFID tag, which is schematically shown in
Output nodes of the multi-stage charge pump 300 are connected to a parallel regulator 302 which primarily controls the supply voltage Vdd to a voltage level of about 1.5 V. Furthermore, the supply voltage Vdd is raised at least to the minimum write voltage of about 1.8 V during a write command execution. This raising leads to a different read and write distance of the tag.
The output nodes of the multi-stage charge pump 300 are further connected to a linear or series regulator 303. The linear regulator 303 comprises a capacity, which forms a storage capacity to ensure relative constant potential and therefore a constant Vdd. That is, the storage capacity may compensate a voltage drop due to an amplitude modulation of the field (AFK) in order to change information with a reader reading the RFID-tag.
The RFID tag schematically shown in
Output of the bandgap circuit 304 is supplied to a logic circuit 305 which generate some logic output signals like POR (Power-on Reset), POK (Power OK), and WOK (Writing OK). For generate these signals the logic circuit 305 is further connected to output nodes (S4 and S6) of the multi-stage charge pump and is supplied by a Bias, i.e. a current source, 306. Furthermore, output of the bandgap circuit 304 is further supplied to the parallel regulator 302 and to the linear regulator 303.
Furthermore, the RFID tag of
Furthermore, in the lower right of
The abbreviations used in
A system of a multi-stage charge pump according to the present invention and an a similar RFID-tag as shown in
The coupling of the system comprising the multi-stage charge pump and the RFID-tag is shown in
It should be noted that the term “comprising” does not exclude other elements or steps and the “a” or “an” does not exclude a plurality. Also elements described in association with different embodiments may be combined.
It should also be noted that reference signs in the claims shall not be construed as limiting the scope of the claims.
Number | Date | Country | Kind |
---|---|---|---|
05108036.4 | Sep 2005 | EP | regional |
PCT/IB2006/052939 | Aug 2006 | IB | international |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB2006/052939 | 8/24/2006 | WO | 00 | 10/24/2008 |