The present invention relates to audio coding and in particular to audio coding based on LPC-like processing in the context of codebooks.
Perceptual audio coders often utilize linear predictive coding (LPC) in order to model the human vocal tract and in order to reduce the amount of redundancy, which can be modeled by the LPC parameters. The LPC residual, which is obtained by filtering the input signal with the LPC filter, is further modeled and transmitted by representing it by one, two or more codebooks (examples are: adaptive codebook, glottal pulse codebook, innovative codebook, transition codebook, hybrid codebooks consisting of predictive and transform parts).
In case of a frame loss, a segment of speech/audio data (typically 10 ms or 20 ms) is lost. To make this loss as less audible as possible, various concealment techniques are applied. These techniques usually consist of extrapolation of the past, received data. This data may be: gains of codebooks, codebook vectors, parameters for modeling the codebooks and LPC coefficients. In all concealment technology known from state-of-the-art, the set of LPC coefficients, which is used for the signal synthesis, is either repeated (based on the last good set) or is extra-/interpolated.
ITU G.718 [1]: The LPC parameters (represented in the ISF domain) are extrapolated during concealment. The extrapolation consists of two steps. First, a long term target ISF vector is calculated. This long term target ISF vector is a weighted mean (with the fixed weighting factorbeta) of
This long term target ISF vector is then interpolated with the last correctly received ISF vector once per frame using a time-varying factor alpha to allow a cross-fade from the last received ISF vector to the long term target ISF vector. The resulting ISF vector is subsequently converted back to the LPC domain, in order to generate intermediate steps (ISFs are transmitted every 20 ms, interpolation generates a set of LPCs every 5 ms). The LPCs are then used to synthesize the output signal by filtering the result of the sum of the adaptive and the fixed codebook, which are amplified with the corresponding codebook gains before addition. The fixed codebook contains noise during concealment. In case of consecutive frame loss, the adaptive codebook is fed back without adding the fixed codebook. Alternatively, the sum signal might be fed back, as done in AMR-WB [5].
In [2], a concealment scheme is described which utilizes two sets of LPC coefficients. One set of LPC coefficients is derived based on the last good received frame, the other set of LPC parameters is derived based on the first good received frame, but it is assumed that the signal evolves in reverse direction (towards the past). Then prediction is performed in two directions, one towards the future and one towards the past. Therefore, two representations of the missing frame are generated. Finally, both signals are weighted and averaged before being played out.
This conventional procedure has certain drawbacks.
In order to cope with changing signal characteristics or in order to converge the LPC envelope towards background noise like-properties, the LPC is changed during concealment by extra/interpolation with some other LPC vectors. There is no possibility to precisely control the energy during concealment. While there is the chance to control the codebook gains of the various codebooks, the LPC will implicitly influence the overall level or energy (even frequency dependent).
It might be envisioned to fade out to a distinct energy level (e.g. background noise level) during burst frame loss. This is not possible with state-of-the-art technology, even by controlling the codebook gains.
It is not possible to fade the noisy parts of the signal to background noise, while maintaining the possibility to synthesize tonal parts with the same spectral property as before the frame loss.
According to an embodiment, an apparatus for generating an error concealment signal may have: an LPC (linear prediction coding) representation generator for generating a replacement LPC representation; an LPC synthesizer for filtering a codebook information using the replacement LPC representation; and a noise estimator for estimating a noise estimate during a reception of good audio frames, wherein the noise estimate depends on the good audio frames, and wherein the LPC representation generator is configured to use the noise estimate estimated by the noise estimator in generating the replacement LPC representation.
According to another embodiment, a method for generating an error concealment signal may have the steps of: generating a replacement LPC representation; filtering a codebook information using the replacement LPC representation; and estimating a noise estimate during a reception of good audio frames, wherein the noise estimate depends on the good audio frames representation, and wherein the noise estimate estimated by the estimating is used in generating the replacement LPC representation.
Another embodiment may have a non-transitory digital storage medium having stored thereon a computer program for performing a method for generating an error concealment signal, having the steps of: generating a replacement LPC representation; filtering a codebook information using the replacement LPC representation; and estimating a noise estimate during a reception of good audio frames, wherein the noise estimate depends on the good audio frames representation, and wherein the noise estimate estimated by the estimating is used in generating the replacement LPC representation, when said computer program is run by a computer.
In an aspect of the present invention, the apparatus for generating an error concealment signal comprises an LPC representation generator for generating a first replacement LPC representation and a different, second replacement LPC representation. Furthermore, an LPC synthesizer is provided for filtering a first codebook information using the first replacement LPC representation to obtain a first replacement signal and for filtering a second different codebook information using the second replacement LPC representation to obtain a second replacement signal. The outputs of the LPC synthesizer are combined by a replacement signal combiner combining the first replacement signal and the second replacement signal to obtain the error concealment signal.
The first codebook is an adaptive codebook for providing the first codebook information and the second codebook as a fixed codebook for providing the second codebook information. In other words, the first codebook represents the tonal part of the signal and the second or fixed codebook represents the noisy part of the signal and therefore can be considered to be a noise codebook.
The first codebook information for the adaptive codebook is generated using a mean value of last good LPC representations, the last good representation and a fading value. Furthermore, the LPC representation for the second or fixed codebook is generated using the last good LPC representation fading value and a noise estimate. Depending on the implementation, the noise estimate can be a fixed value, an offline trained value or it can be adaptively derived from a signal preceding an error concealment situation.
An LPC gain calculation for calculating an influence of a replacement LPC representation is performed and this information is then used in order to perform a compensation so that the power or loudness or, generally, an amplitude-related measure of the synthesis signal is similar to the corresponding synthesis signal before the error concealment operation.
In a further aspect, an apparatus for generating an error concealment signal comprises an LPC representation generator for generating one or more replacement LPC representations. Furthermore, the gain calculator is provided for calculating the gain information from the LPC representation and a compensator is then additionally provided for compensating a gain influence of the replacement LPC representation and this gain compensation operates using the gain operation provided by the gain calculator. An LPC synthesizer then filters a codebook information using the replacement LPC representation to obtain the error concealment signal, wherein the compensator is configured for weighting the codebook information before being synthesized by the LPC synthesizer or for weighting the LPC synthesis output signal. Thus, any gain or power or amplitude-related perceivable influence at the onset of an error concealment situation is reduced or eliminated.
This compensation is not only useful for individual LPC representations as outlined in the above aspect, but is also useful in the case of using only a single LPC replacement representation together with a single LPC synthesizer.
The gain values are determined by calculating impulse responses of the last good LPC representation and a replacement LPC representation and by particularly calculating an rms value over the impulse response of the corresponding LPC representation over a certain time which is between 3 and 8 ms and is advantageously 5 ms.
In an implementation, the actual gain value is determined by dividing a new rms value, i.e. an rms value for a replacement LPC representation by an rms value of good LPC representation.
The single or several replacement LPC representations is/are calculated using a background noise estimate which is a background noise estimate derived from the currently decoded signals in contrast to an offline trained vector simply predetermined noise estimate.
In a further aspect, an apparatus for generating a signal comprises an LPC representation generator for generating one or more replacement LPC representations, and an LPC synthesizer for filtering a codebook information using the replacement LPC representation. Additionally, a noise estimator for estimating a noise estimate during a reception of good audio frames is provided, and this noise estimate depends on the good audio frames. The representation generator is configured to use the noise estimate estimated by the noise estimator in generating the replacement LPC representation.
Spectral representation of a past decoded signal is process to provide a noise spectral representation or target representation. The noise spectral representation is converted into a noise LPC representation and the noise LPC representation is the same kind of LPC representation as the replacement LPC representation. ISF vectors or LSF vectors are advantageous for the specific LPC-related processing procedures.
Estimate is derived using a minimum statistics approach with optimal smoothing to a past decoded signal. This spectral noise estimate is then converted into a time domain representation. Then, a Levinson-Durbin recursion is performed using a first number of samples of the time domain representation, where the number of samples is equal to an LPC order. Then, the LPC coefficients are derived from the result of the Levinson-Durbin recursion and this result is finally transformed in a vector. The aspect of using individual LPC representations for individual codebooks, the aspect of using one or more LPC representations with a gain compensation and the aspect of using a noise estimate in generating one or more LPC representations, which estimate is not an offline-trained vector but is a noise estimate derived from the past decoded signal are individually useable for obtaining an improvement with respect to conventional technology.
Additionally, these individual aspects can also be combined with each other so that, for example, the first aspect and the second aspect can be combined or the first aspect or the third aspect can be combined or the second aspect and the third aspect can be combined to each other to provide an even improved performance with respect to conventional technology. Even more advantageously, all three aspects can be combined with each other to obtain improvements over conventional technology. Thus, even though the aspects are described by separate figures all aspects can be applied in combination with each other, as can be seen by referring to the enclosed figures and description.
Embodiments of the present invention will be detailed subsequently referring to the appended drawings, in which:
Embodiments of the present invention relate to controlling the level of the output signal by means of the codebook gains independently of any gain change caused by an extrapolated LPC and to control the LPC modeled spectral shape separately for each codebook. For this purpose, separate LPCs are applied for each codebook and compensation means are applied to compensate for any change of the LPC gain during concealment.
Embodiments of the present invention as defined in the different aspects or in combined aspects have the advantage of providing a high subjective quality of speech/audio in case of one or more data packets not being correctly or not being received at all at the decoder side.
Furthermore, the embodiments compensate the gain differences between subsequent LPCs during concealment, which might result from the LPC coefficients being changed over time, and therefore unwanted level changes are avoided.
Furthermore, embodiments are advantageous in that during concealment two or more sets of LPC coefficients are used to independently influence the spectral behavior of voiced and unvoiced speech parts and also tonal and noise-like audio parts.
All aspects of the present invention provide an improved subjective audio quality.
According to one aspect of this invention, the energy is precisely controlled during the interpolation. Any gain that is introduced by changing the LPC is compensated.
According to another aspect of this invention, individual LPC coefficient sets are utilized for each of the codebook vectors. Each codebook vector is filtered by its corresponding LPC and the individual filtered signals are just afterwards summed up to obtain the synthesized output. In contrast, state-of-the-art technology first adds up all excitation vectors (being generated from different codebooks) and just then feeds the sum to a single LPC filter.
According to another aspect, a noise estimate is not used, for example as an offline-trained vector, but is actually derived from the past decoded frames so that, after a certain amount of erroneous or missing packets/frames, a fade-out to the actual background noise rather than any predetermined noise spectrum is obtained. This particularly results in a feeling of acceptance at a user side, but to the fact that even when an error situation occurs, the signal provided by the decoder after a certain number of frames is related to the preceding signal. However, the signal provided by a decoder in the case of a certain number of lost or erroneous frames is a signal completely unrelated to the signal provided by the decoder before an error situation.
Applying gain compensation for the time-varying gain of the LPC allows the following advantages:
It compensates any gain that is introduced by changing the LPC.
Hence, the level of the output signal can be controlled by the codebook gains of the various codebooks. This allows for a pre-determined fade-out by eliminating any unwanted influence by the interpolated LPC.
Using a separate set of LPC coefficients for each codebook used during concealment allows the following advantages:
It creates the possibility to influence the spectral shape of tonal and noise like parts of the signal separately.
It gives the chance to play out the voiced signal part almost unchanged (e.g. desired for vowels), while the noise part may quickly be converging to background noise.
It gives the chance to conceal voiced parts, and fade out the voiced part with arbitrary fading speed (e.g. fade out speed dependent from signal characteristics), while simultaneously maintaining the background noise during concealment. State-of-the-art codecs usually suffer from a very clean voiced concealment sound.
It provides means to fade to background noise during concealment smoothly, by fading out the tonal parts without changing the spectral properties, and fading the noise like parts to the background spectral envelope.
Typically, the LPC synthesis output signals are time domain signals and the replacement signal combiner 110 performs a synthesis output signal combination by performing a synchronized sample-by-sample addition. However, other combinations, such as a weighted sample-by-sample addition or a frequency domain addition or any other signal combination can be performed by the replacement signal combiner 110 as well.
Furthermore, the first codebook 102 is indicated as comprising an adaptive codebook and the second codebook 104 is indicated as comprising a fixed codebook. However, the first codebook and the second codebook can be any codebooks such as a predictive codebook as the first codebook and a noise codebook as the second codebook. However, other codebooks can be glottal pulse codebooks, innovative codebooks, transition codebooks, hybrid codebooks consisting of predictive and transform parts, codebooks for individual voice generators such as males/females/children or codebooks for different sounds such as for animal sounds, etc.
Furthermore,
For the state-of-the-art just one LPC is applied. For the newly proposed method, each excitation vector, which is generated by either the adaptive or the fixed codebook, is filtered by its own set of LPC coefficients. The derivation of the individual ISF vectors is as follows:
Coefficient set A (for filtering the adaptive codebook) is determined by this formula:
where alphaA is a time varying adaptive fading factor which may depend on signal stability, signal class, etc. isf−x are the ISF coefficients, where x denotes the frame number, relative to the end of the current frame: x=−1 denotes the first lost ISF, x=−2 the last good, x=−3 second last good and so on.
This leads to fading the LPC which is used for filtering the tonal part, starting from the last correctly received frame towards the average LPC (averaged over three of the last good 20 ms frames). The more frames get lost, the closer the ISF, which is used during concealment, will be to this short term average ISF vector (isf′). Generally, it is to be noted that ISF stands for values in an ISF domain or in an LSF domain. Hence, the same calculations or slightly different calculations can also be performed in the LSF domain rather than in the ISF domain or any other similar domain.
Advantageously, a coefficient set B (for filtering the fixed codebook) is determined by this formula:
isf
B
−1=alphaB·isf−2+(1−beta)·isfcng(block 146)
where isfcng is the ISF coefficient set derived from a background noise estimate and alphaB is the time-varying fading speed factor which is signal dependent. The target spectral shape is derived by tracing the past decoded signal in the FFT domain (power spectrum), using a minimum statistics approach with optimal smoothing, similar to [3]. This FFT estimate is converted to the LPC representation by calculating the auto-correlation by doing inverse FFT and then using Levinson-Durbin recursion to calculate LPC coefficients using the first N samples of the inverse FFT, where N is the LPC order. Hence, the Levinson Durbin recursion is calculated on auto-correlated values or the time domain representation based on which the recursion is calculated comprises an inverse of a squared Fourier Transform (e.g. FFT) spectrum.
This LPC is then converted into the ISF domain to retrieve isfcng. Alternatively—if such tracing of the background spectral shape is not available—the target spectral shape might also be derived based on any combination of an offline trained vector and the short-term spectral mean, as it is done in G.718 for the common target spectral shape.
The fading factors A and αB are determined depending on the decoded audio signal, i.e., depending on the decoded audio signal before the occurrence of an error. The fading factor may depend on signal stability, signal class, etc. Thus, is the signal is determined to be a quite noisy signal, then the fading factor is determined in such a way that the fading factor decreases, from time to time, more quickly than compared to a situation where a signal is quite tonal. In this situation, the fading factor decreases from one time frame to next time frame by a reduced amount. This makes sure that the fading out from the last good frame to the mean value of the last three good frames takes place more quickly in the case of noisy signals compared to non-noisy or tonal signals, where the fading out speed is reduced. Similar procedures can be performed for signal classes. For voiced signals, a fading out can be performed slower than for unvoiced signals or for music signals a certain fading speed can be reduced compared to further signal characteristics and corresponding determinations of the fading factor can be applied.
As discussed in the context of
However, if an error concealment situation is detected by the error concealment controller 202 of
Furthermore, depending on the signal class, a controller 409 controls the switch 405 in order to either feedback a combination of both codebook outputs (subsequent to the application of the corresponding codebook gain) or to only feedback the adaptive codebook output.
In accordance with an embodiment, the data for the LPC synthesis filter A 106 and the data for the LPC synthesis filter B 108 is generated by the LPC representation generator 100 of
Subsequently, the switching from the normal mode to the concealment mode on one hand and from the concealment mode back to the normal mode is discussed.
The transition from one common to several separate LPCs when switching from clean channel decoding to concealment does not cause any discontinuities, as the memory state of the last good LPC may be used to initialize each AR or MA memory of the separate LPCs. When doing so, a smooth transition from the last good to the first lost frame is ensured.
When switching from concealment to clean channel decoding (recovery phase), the approach of the separate LPCs introduces the challenge to correctly update the internal memory state of the single LPC filter during clean-channel decoding (usually AR (auto-regressive) models are used). Just using the AR memory of one LPC or an averaged AR memory would lead to discontinuities at the frame border between the last lost and the first good frame. In the following a method is described to overcome deal with this challenge:
A small portion of all excitation vectors (suggestion: 5 ms) is added at the end of any concealed frame. This summed excitation vector may then be fed to the LPC which would be used for recovery. This is shown in
It is advisable to start at frame end minus 5 ms, setting the LPC AR memory to zero, derive the LPC synthesis by using any of the individual LPC coefficient sets and save the memory state at the very end of the concealed frame. If the next frame is correctly received, this memory state may then be used for recovery (meaning: used for initializing the start-of-frame LPC memory), otherwise it is discarded. This memory has to be additionally introduced; it has to be handled separately from any of the used LPC AR memories of the concealment used during concealment.
Another solution for recovery is to use the method LPC0, known from USAC [4].
Subsequently,
Furthermore, the additional recovery LPC synthesizer X indicated at 418 is shown which receives, as an input, a sum of at least a small portion of all excitation vectors such as 5 ms. This excitation vector is input into the LPC synthesizer X 418 memory states of the LPC synthesis filter X.
Then, when a switchback from the concealment mode to the normal mode occurs, the single LPC synthesis filter is controlled by copying the internal memory states of the LPC synthesis filter X into this single normal operating filter and additionally the coefficients of the filter are set by the correctly transmitted LPC representation.
Additionally, as already discussed in the context of
Compensator 406, 408 partly or fully compensates a gain influence of the first replacement LPC in the first gain information and compensates a gain influence of the second replacement LPC representation using the second gain information.
In an embodiment, the calculator 600 is configured to calculate a last good power information related to a last good LPC representation before a start of the error concealment. Furthermore, the gain calculator 600 calculates a first power information for the first replacement LPC representation, a second power information for the second LPC representation, the first gain value using the last good power information and the first power information, and a second gain value using the last good power information and the second power information. Then, the compensation is performed in the compensator 406, 408 using the first gain value and using the second gain value. Depending on the information, however, the calculation of the last good power information can also be performed, as illustrated in the
In particular, the gain calculator 600 is configured to calculate from the last good LPC representation or the first and second LPC replacement representations an impulse response and to then calculate an rms (root mean square) value from the impulse response to obtain the correspondent power information in the gain compensation, each excitation vector is—after being gained by the corresponding codebook gain—again amplified by the gains: gA or gB. These gains are determined by calculating the impulse response of the currently used LPC and then calculating the rms:
The result is then compared to the rms of the last correctly received LPC and the quotient is used as gain factor in order to compensate for energy increase/loss of LPC interpolation:
This procedure can be seen as a kind of normalization. It compensates the gain, which is caused by LPC interpolation.
Subsequently,
To this end, several steps are performed in an embodiment as illustrated in
Subsequently, a further aspect is discussed, i.e. an implementation for an apparatus for generating an error concealment signal which ha the LPC representation generator 100 generating only a single replacement LPC representation, such as for the situation illustrated in
The other procedures for the LPC representation generator, the gain calculator, the compensator and the LPC synthesizer can be performed in the same way as discussed in the context of
As has been outlined in the context of
Then a manipulator 1004 is provided which together performs the operations of for example amplifiers 402, 406 to the codebook information of a single codebook or to the codebook information of two or more codebooks in order to finally obtain a manipulated signal such as a codebook signal or a concealment signal, depending on whether the manipulator 1004 is located before the LPC synthesizer in
The noise estimator is configured to process a spectral representation of a past decoded signal to provide a noise spectral representation and to convert the noise spectral representation into a noise LPC representation, where the noise LPC representation is the same kind of an LPC representation as the replacement LPC representation. Thus, when the replacement LPC representation is in the ISF-domain representation or an ISF vector, then the noise LPC representation additionally is an ISF vector or ISF representation.
Furthermore, the noise estimator 206 is configured to apply a minimum statistics approach with optimal smoothing to a past decoded signal to derive the noise estimate. For this procedure, it is advantageous to perform the procedure illustrated in [3]. However, other noise estimation procedures relying on, for example, suppression of tonal parts compared to non-tonal parts in a spectrum in order to filter out the background noise or noise in an audio signal can be applied as well for obtaining the target spectral shape or noise spectral estimate.
Thus, in one embodiment, a spectral noise estimate is derived from a past decoded signal and the spectral noise estimate is then converted into an LPC representation and then into an ISF domain to obtain the final noise estimate or target spectral shape.
In an embodiment illustrated in
Subsequently,
In step 1300, a mean value of two or three last good frames is calculated. In step 1302, the last good frame LPC representation is provided. Furthermore, in step 1304, a fading factor is provided which can be controlled, for example, by a separate signal analyzer which can be, for example, included in the error concealment controller 200 of
In the context of calculating a single LPC replacement representation, the outputs of blocks 1300, 1304, 1306 are provided to the calculator 1308. Then, a single replacement LPC representation is calculated in such a way that subsequent to a certain number of lost or missing or erroneous frames/packets, the fading over to the noise estimate LPC representation is obtained.
However, individual LPC representations for an individual codebook, such as for the adaptive codebook and the fixed codebook, are calculated as indicated at block 1310, then the procedure as discussed before for calculating ISFA−1 (LPC A) on the hand and the calculation of ISFB−1 (LPC B) is performed.
Although the present invention has been described in the context of block diagrams where the blocks represent actual or logical hardware components, the present invention can also be implemented by a computer-implemented method. In the latter case, the blocks represent corresponding method steps where these steps stand for the functionalities performed by corresponding logical or physical hardware blocks.
Although some aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus. Some or all of the method steps may be executed by (or using) a hardware apparatus, like for example, a microprocessor, a programmable computer or an electronic circuit. In some embodiments, some one or more of the most important method steps may be executed by such an apparatus.
Depending on certain implementation requirements, embodiments of the invention can be implemented in hardware or in software. The implementation can be performed using a digital storage medium, for example a floppy disc, a DVD, a Blu-Ray, a CD, a ROM, a PROM, and EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed. Therefore, the digital storage medium may be computer readable.
Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.
Generally, embodiments of the present invention can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer. The program code may, for example, be stored on a machine readable carrier.
Other embodiments comprise the computer program for performing one of the methods described herein, stored on a machine readable carrier.
In other words, an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.
A further embodiment of the inventive method is, therefore, a data carrier (or a non-transitory storage medium such as a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein. The data carrier, the digital storage medium or the recorded medium are typically tangible and/or non-transitory.
A further embodiment of the invention method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein. The data stream or the sequence of signals may, for example, be configured to be transferred via a data communication connection, for example, via the internet.
A further embodiment comprises a processing means, for example, a computer or a programmable logic device, configured to, or adapted to, perform one of the methods described herein.
A further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.
A further embodiment according to the invention comprises an apparatus or a system configured to transfer (for example, electronically or optically) a computer program for performing one of the methods described herein to a receiver. The receiver may, for example, be a computer, a mobile device, a memory device or the like. The apparatus or system may, for example, comprise a file server for transferring the computer program to the receiver.
In some embodiments, a programmable logic device (for example, a field programmable gate array) may be used to perform some or all of the functionalities of the methods described herein. In some embodiments, a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein. Generally, the methods are performed by any hardware apparatus.
While this invention has been described in terms of several advantageous embodiments, there are alterations, permutations, and equivalents which fall within the scope of this invention. It should also be noted that there are many alternative ways of implementing the methods and compositions of the present invention. It is therefore intended that the following appended claims be interpreted as including all such alterations, permutations, and equivalents as fall within the true spirit and scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
14160774.7 | Mar 2014 | EP | regional |
14167003.4 | May 2014 | EP | regional |
14178761.4 | Jul 2014 | EP | regional |
This application is a continuation of U.S. patent application Ser. No. 16/178,179 filed Nov. 1, 2018, which is a divisional of U.S. patent application Ser. No. 15/267,809 filed Sep. 16, 2016 (issued as U.S. Pat. No. 10,163,444 issued Dec. 25, 2018), which is a continuation of International Application No. PCT/EP2015/054486, filed Mar. 4, 2015, which is incorporated herein by reference in its entirety, and additionally claims priority from European Applications Nos. EP EP14160774.7, filed Mar. 19, 2014, EP 14167003.4, filed May 5, 2014 and EP 14178761.4, filed Jul. 28, 2014, which are all incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
Parent | 15267809 | Sep 2016 | US |
Child | 16178179 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16178179 | Nov 2018 | US |
Child | 16833211 | US | |
Parent | PCT/EP2015/054486 | Mar 2015 | US |
Child | 15267809 | US |